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The New Genetics is available online at http://publications.nigms.nih.gov/ thenewgenetics. Produced by the Office of Communications and Public Liaison National Institute of General Medical Sciences National Institutes of Health U.S. Department of Health and Human Services NATIONAL INSTITUTES OF HEALTH NATIONAL INSTITUTE OF GENERAL MEDICAL SCIENCES OFFICE OF COMMUNICATIONS AND PUBLIC LIAISON 45 CENTER DR RM 3AN.32 MSC 6200 BETHESDA MD 20814-9692 The New Genetics NIH Publication No.10 - 662 Revised April 2010 http://www.nigms.nih.gov Contents F O RE W O RD 2 C H A P TE R 1 : H O W G E N E S W O RK 4 Beautiful DNA 5 Copycat 8 Let’s Call It Even 9 Getting the Message 11 Nature’s Cut-and-Paste Job 14 All Together Now 16 Genetics and You: Nursery Genetics 17 Found in Translation 18 RNA Surprises 19 An Interesting Development 20 The Tools of Genetics: Mighty Microarrays 22 C H A P TE R 2 : RN A A N D D N A RE VE A LE D : N E W RO LE S , N E W RU LE S 24 RNA World 25 Molecular Editor 26 Healthy Interference 29 Dynamic DNA 30 Secret Code 30 Genetics and You: The Genetics of Anticipation 32 Battle of the Sexes 33 Starting at the End 34 The Other Human Genome 36 The Tools of Genetics: Recombinant DNA and Cloning 38 C H A P TE R 3 : LI F E ’ S G E N E TI C TRE E 40 Everything Evolves 40 Selective Study 42 Clues from Variation 43 Living Laboratories 46 The Genome Zoo 52 Genes Meet Environment 53 Genetics and You: You’ve Got Rhythm! 56 Animals Helping People 58 My Collaborator Is a Computer 58 The Tools of Genetics: Unlimited DNA 60 C H A P TE R 4 : G E N E S A RE U S 62 Individualized Prescriptions 64 The Healing Power of DNA 65 Cause and Effect 67 Us vs. Them 68 Genetics and You: Eat Less, Live Longer? 69 Gang Warfare 70 The Tools of Genetics: Mathematics and Medicine 72 C H A P TE R 5 : 2 1 S T- C E N TU RY G E N E TI C S 74 No Lab? No Problem! 76 Hard Questions 78 Good Advice 80 Genetics and You: Crime-Fighting DNA 81 Genetics, Business, and the Law 82 Careers in Genetics 85 The Tools of Genetics: Informatics and Databases 86 G LO S SA RY 88 Foreword Consider just three of Earth’s inhabitants: And every living thing does one thing the same a bright yellow daffodil that greets the way: To make more of itself, it first copies its spring, the single-celled creature called Thermococcus that lives in boiling hot molecular instruction manual—its genes—and then passes this information on to its offspring. This cycle has been springs, and you. Even a science-fiction repeated for three and a half billion years. But how did we and our very distant rela- writer inventing a story set on a distant planet could hardly imagine three more dif- tives come to look so different and develop so many different ways of getting along in the world? A century ago, researchers began to answer ferent forms of life. Yet you, Thermococcus that question with the help of a science called genetics. Get a refresher course on the basics in and the daffodil are related! Indeed, all of the Earth’s billions of living things are kin Chapter 1, “How Genes Work.” It’s likely that when you think of heredity you think first of DNA, but in the past few years, to each other. researchers have made surprising findings about The New Genetics I Foreword 3 another molecular actor that plays a starring role. Can DNA and RNA help doctors predict Check out the modern view of RNA in Chapter 2, whether we’ll get diseases like cancer, diabetes or “RNA and DNA Revealed: New Roles, New Rules.” asthma? What other mysteries are locked within When genetics first started, scientists didn’t the 6 feet of DNA inside nearly every cell in our have the tools they have today. They could only bodies? Chapter 4, “Genes Are Us,” explains what look at one gene, or a few genes, at a time. Now, researchers know, and what they are still learning, researchers can examine all of the genes in a liv- about the role of genes in health and disease. ing organism—its genome—at once. They are Finally, in Chapter 5, “21st-Century doing this for organisms on every branch of the Genetics,” see a preview of things to come. Learn tree of life and finding that the genomes of mice, how medicine and science are changing in big frogs, fish and a slew of other creatures have ways, and how these changes influence society. many genes similar to our own. So why doesn’t your brother look like your dog or the fish in your aquarium? It’s because of evolution. In Chapter 3, “Life’s Genetic Tree,” find out how evolution works and how it relates to genetics and medical research. From metabolism to medicines to agriculture, the science of genetics affects us every day. It is part of life … part of your life! CHAPTER 1 How Genes Work P eople have known for many years that living things inherit traits from their parents. Proteins do many other things, too. They provide the body’s main building materials, That common-sense observation led to agricul- forming the cell’s architecture and structural ture, the purposeful breeding and cultivation of components. But one thing proteins can’t do is animals and plants for desirable characteristics. make copies of themselves. When a cell needs Firming up the details took quite some time, more proteins, it uses the manufacturing instruc- though. Researchers did not understand exactly tions coded in DNA. how traits were passed to the next generation until the middle of the 20th century. Now it is clear that genes are what carry our The DNA code of a gene—the sequence of its individual DNA building blocks, labeled A (adenine), T (thymine), C (cytosine) and G traits through generations and that genes are (guanine) and collectively called nucleotides— made of deoxyribonucleic acid (DNA). But spells out the exact order of a protein’s building genes themselves don’t do the actual work. blocks, amino acids. Rather, they serve as instruction books for mak- Occasionally, there is a kind of typographical ing functional molecules such as ribonucleic error in a gene’s DNA sequence. This mistake— acid (RNA) and proteins, which perform the which can be a change, gap or duplication—is chemical reactions in our bodies. called a mutation. Genetics in the Garden In 1900, three European scientists independently discovered an obscure research paper that had been published nearly 35 years before. Written by Gregor Mendel, an Austrian monk who was also a scientist, the report described a series of breeding experiments performed with pea plants growing in his abbey garden. Mendel had studied how pea plants inherited the two variant forms of easy-to-see traits. These included flower color (white or purple) and the texture of the peas (smooth or wrinkled). Mendel counted many generations of pea plant The monk Gregor Mendel first described how traits are inherited from one generation to the next. offspring and learned that these characteristics were passed on to the next generation in orderly, predictable ratios. When he cross-bred purple-flowered pea plants with white-flowered ones, the next generation had only purple flowers. But directions for making white flowers were hidden somewhere in the peas of that generation, because when those purple-flowered The New Genetics I How Genes Work 5 A mutation can cause a gene to encode a Beautiful DNA protein that works incorrectly or that doesn’t Up until the 1950s, scientists knew a good deal work at all. Sometimes, the error means that no about heredity, but they didn’t have a clue what protein is made. DNA looked like. In order to learn more about But not all DNA changes are harmful. Some DNA and its structure, some scientists experi- mutations have no effect, and others produce mented with using X rays as a form of molecular new versions of proteins that may give a survival photography. advantage to the organisms that have them. Over Rosalind Franklin, a physical chemist work- time, mutations supply the raw material from ing with Maurice Wilkins at King’s College in which new life forms evolve (see Chapter 3, London, was among the first to use this method “Life’s Genetic Tree”). to analyze genetic material. Her experiments plants were bred to each other, some of their offspring had white flowers. What’s more, the second-generation plants displayed the colors in a predictable pattern. On average, 75 percent of the second-generation plants had purple flowers and 25 percent of the plants had white flowers. Those same ratios persisted, and were reproduced when the experiment was repeated many times over. Trying to solve the mystery of the missing color blooms, Mendel imagined that the reproductive cells of his pea plants might contain discrete “factors,” each of which specified a particular trait, such as white flowers. Mendel reasoned that the factors, whatever they were, must be physical material because they passed from parent to offspring in a mathematically orderly way. It wasn’t until many years later, when the other scientists unearthed Mendel’s report, that the factors were named genes. Early geneticists quickly discovered that Mendel’s mathematical rules of inheritance applied not just to peas, but also to all plants, animals and people. The discovery of a quantitative rule for inheritance was momentous. It revealed that a common, general principle governed the growth and development of all life on Earth. 6 National Institute of General Medical Sciences produced what were referred to at the time as COLD SPRING HARBOR LABORATORY ARCHIVES “the most beautiful X-ray photographs of any substance ever taken.” Other scientists, including zoologist James Watson and physicist Francis Crick, both working at Cambridge University in the United Kingdom, were trying to determine the shape of DNA too. Ultimately, this line of research In 1953, Watson and Crick created their historic model of the shape of DNA: the double helix. revealed one of the most profound scientific discoveries of the 20th century: that DNA exists handrails—were complementary to each other, as a double helix. and this unlocked the secret of how genetic The 1962 Nobel Prize in physiology or medicine was awarded to Watson, Crick and Wilkins In genetics, complementary means that if for this work. Although Franklin did not earn a you know the sequence of nucleotide building share of the prize due to her untimely death at age blocks on one strand, you know the sequence of 38, she is widely recognized as having played a nucleotide building blocks on the other strand: significant role in the discovery. The spiral staircase-shaped double helix has attained global status as the symbol for DNA. But what is so beautiful about the and groups of genes are packaged tightly into structures called chromosomes. Every cell in your contains a full set of chromosomes in its nucleus. If the chromosomes in one of your cells were structure of DNA taught uncoiled and placed end to end, the DNA would researchers a fundamental be about 6 feet long. If all the DNA in your body strands—winding together like parallel OREGON STATE UNIVERSITY LIBRARIES Long strings of nucleotides form genes, ladder structure isn’t just them that the two connected original X-ray diffraction photo revealed the physical structure of DNA. to G (see drawing, page 7). body except for eggs, sperm and red blood cells lesson about genetics. It taught Rosalind Franklin’s A always matches up with T and C always links discovery of the twisting its good looks. Rather, the SPECIAL COLLECTIONS information is stored, transferred and copied. were connected in this way, it would stretch approximately 67 billion miles! That’s nearly 150,000 round trips to the Moon. The New Genetics I How Genes Work 7 DNA Structure The long, stringy DNA that makes up genes is spooled within chromosomes inside the nucleus of a cell. (Note that a gene would actually be a much longer stretch of DNA than what is shown here.) Chromosome Nucleus G Cell C T G C G Guanine Cytosine C A T C G Thymine T Gene G C T DNA consists of two long, twisted chains made up of nucleotides. Each nucleotide contains one base, one phosphate molecule and the sugar molecule deoxyribose. The bases in DNA nucleotides are adenine, thymine, cytosine and guanine. P Nucleotide S C T C G A Adenine A A Sugarphosphate backbone Bases G A DNA C 8 National Institute of General Medical Sciences Copycat It’s astounding to think that your body consists of trillions of cells. But what’s most amazing is that it all starts with one cell. How does this massive expansion take place? As an embryo progresses through development, its cells Humans have 23 pairs of chromosomes. Male DNA (pictured here) contains an X and a Y chromosome, whereas female DNA contains two X chromosomes. must reproduce. But before a cell divides into two new, CYTOGENETICS LABORATORY, BRIGHAM AND WOMEN’S HOSPITAL nearly identical cells, it must copy its DNA so there will be a complete set of the complementary new strand. The process, genes to pass on to each of the new cells. called replication, is astonishingly fast and To make a copy of itself, the twisted, com- accurate, although occasional mistakes, such as pacted double helix of DNA has to unwind and deletions or duplications, occur. Fortunately, a separate its two strands. Each strand becomes cellular spell-checker catches and corrects nearly a pattern, or template, for making a new strand, all of these errors. so the two new DNA molecules have one new strand and one old strand. The copy is courtesy of a cellular protein Mistakes that are not corrected can lead to diseases such as cancer and certain genetic disorders. Some of these include Fanconi anemia, early machine called DNA polymerase, which reads aging diseases and other conditions in which the template DNA strand and stitches together people are extremely sensitive to sunlight and some chemicals. DNA copying is not the only time when DNA damage can happen. Prolonged, unprotected sun exposure can cause DNA changes that lead to skin cancer, and toxins in cigarette smoke can cause lung cancer. When DNA polymerase makes an error while copying a gene’s DNA sequence, the mistake is called a mutation. In this example, the nucleotide G has been changed to an A. The New Genetics I How Genes Work 9 C G A T C It may seem ironic, then, that many drugs G A used to treat cancer work by attacking DNA. That’s T T A because these chemotherapy drugs disrupt the DNA copying process, which goes on much faster C G T in rapidly dividing cancer cells than in other A G cells of the body. The trouble is that most of these C T drugs do affect normal cells that grow and A T divide frequently, such as cells of the immune system and hair cells. A Understanding DNA replication better could A A G T T be a key to limiting a drug’s action to cancer A G cells only. C A G T G C A T T C G Let’s Call It Even After copying its DNA, a cell’s next challenge is C New strand G getting just the right amount of genetic material into each of its two offspring. C C A G Most of your cells are called diploid G T A C A (“di” means two, and “ploid” refers to sets of C T G T C A T chromosomes) because they have two sets of chromosomes (23 pairs). Eggs and sperm are A different; these are known as haploid cells. Each G so that at fertilization the math will work out: A A C C haploid cell has only one set of 23 chromosomes T G G C T A C G T A haploid egg cell will combine with a haploid sperm cell to form a diploid cell with the right A number of chromosomes: 46. T A Chromosomes are numbered 1 to 22, according to size, with 1 being the largest chromosome. The 23rd pair, known as the sex chromosomes, are called X and Y. In humans, abnormalities of chromosome number usually occur during meiosis, the time when a cell During DNA replication, each strand of the original molecule acts as a template for the synthesis of a new, complementary DNA strand. T T 10 National Institute of General Medical Sciences Meiosis Chromosomes from parents During meiosis, chromosomes from both parents are copied and paired to exchange portions of DNA. Cell nucleus Chromosomes replicate Matching chromosomes pair up This creates a mix of new genetic material in the offspring’s cells. Nucleus divides into daughter nuclei Daughter nuclei divide again Chromosomes swap sections of DNA Chromosome pairs divide Chromosomes divide; daughter nuclei have single chromosomes and a new mix of genetic material The New Genetics I How Genes Work 11 reduces its chromosomes from diploid to haploid in creating eggs or sperm. What happens if an egg or a sperm cell gets Amon has made major progress in understanding the details of meiosis. Her research shows how, in healthy cells, gluelike protein complexes the wrong number of chromosomes, and how called cohesins release pairs of chromosomes at often does this happen? exactly the right time. This allows the chromo- Molecular biologist Angelika Amon of the Massachusetts Institute of Technology in somes to separate properly. These findings have important implications Cambridge says that mistakes in dividing DNA for understanding and treating infertility, birth between daughter cells during meiosis are the defects and cancer. leading cause of human birth defects and miscarriages. Current estimates are that 10 percent of all embryos have an incorrect chromosome number. Most of these don’t go to full term and are miscarried. In women, the likelihood that chromosomes Getting the Message So, we’ve described DNA—its basic properties and how our bodies make more of it. But how does DNA serve as the language of life? How do you get a protein from a gene? won’t be apportioned properly increases with age. One of every 18 babies born to women over 45 has three copies of chromosome 13, 18 or 21 instead of the normal two, and this improper balancing can cause trouble. For example, three copies of chromosome 21 lead to Down syndrome. To make her work easier, Amon—like many other basic scientists—studies yeast cells, which separate their chromosomes almost exactly the same way human cells do, except that yeast do it much faster. A yeast cell copies its DNA and produces daughter cells in about 11/2 hours, compared to a whole day for human cells. The yeast cells she uses are the same kind bakeries use to make bread and breweries use to make beer! Trisomy, the hallmark of Down syndrome, results when a baby is born with three copies of chromosome 21 instead of the usual two. 12 National Institute of General Medical Sciences There are two major steps in making a You’d think that for a process so essential to protein. The first is transcription, where the life, researchers would know a lot about how information coded in DNA is copied into RNA. transcription works. While it’s true that the The RNA nucleotides are complementary to basics are clear—biologists have been studying those on the DNA: a C on the RNA strand gene transcribing by RNA polymerases since matches a G on the DNA strand. these proteins were first discovered in 1960— The only difference is that RNA pairs a some of the details are actually still murky. nucleotide called uracil (U), instead of a T, with an A on the DNA. A protein machine called RNA polymerase reads the DNA and makes the RNA copy. This 1 copy is called messenger RNA, or mRNA, because it delivers the gene’s message to the proteinproducing machinery. A C A T T G T A At this point you may be wondering why all of the cells in the human body aren’t exactly alike, since they all contain the same DNA. What makes a liver cell different from a brain cell? How do the cells in the heart make the organ contract, but those in skin allow us to sweat? Cells can look and act differently, and do entirely different jobs, because each cell “turns on,” or expresses, only the genes appropriate for what it needs to do. That’s because RNA polymerase does not work alone, but rather functions with the aid of many helper proteins. While the core part of RNA polymerase is the same in all cells, the helpers vary in different cell types throughout the body. DNA RNA polymerase transcribes DNA to make messenger RNA (mRNA). The New Genetics I How Genes Work 13 The biggest obstacle to learning more But our understanding is improving fast, has been a lack of tools. Until fairly recently, thanks to spectacular technological advances. researchers were unable to get a picture at the We have new X-ray pictures that are far more atomic level of the giant RNA polymerase pro- sophisticated than those that revealed the structure tein assemblies inside cells to understand how of DNA. Roger Kornberg of Stanford University in the many pieces of this amazing, living machine California used such methods to determine the do what they do, and do it so well. structure of RNA polymerase. This work earned 2 3 Threonine 4 Arginine Amino acids Tyrosine DNA strand Threonine RNA strand Amino acids link up to make a protein. A C A T G C T A T G C A A T tRNA C G A T U A G C C G U A A T UA C G G C T A Ribosome A C G Codon 1 U A Codon 2 U C G U Codon 3 mRNA The mRNA sequence (dark red strand) is complementary to the DNA sequence (blue strand). On ribosomes, transfer RNA (tRNA) helps convert mRNA into protein. A C Codon 4 A 14 National Institute of General Medical Sciences him the 2006 Nobel Nature’s Cut-and-Paste Job Prize in chemistry. In Several types of RNA play key roles in making addition, very powerful a protein. The gene transcript (the mRNA) microscopes and other transfers information from DNA in the nucleus to tools that allow us to the ribosomes that make protein. Ribosomal RNA watch one molecule forms about 60 percent of the ribosomes. Lastly, at a time provide a transfer RNA carries amino acids to the ribo- new look at RNA poly- somes. As you can see, all three types of cellular merase while it’s at work RNAs come together to produce new proteins. reading DNA and producing RNA. For example, Steven RNA polymerase (green) and one end of a DNA strand (blue) are attached to clear beads pinned down in two optical traps. As RNA polymerase moves along the DNA, it creates an RNA copy of a gene, shown here as a pink strand. STEVEN BLOCK But the journey from gene to protein isn’t quite as simple as we’ve just made it out to be. After transcription, several things need to hap- Block, also of Stanford, pen to mRNA before a protein can be made. For has used a physics tech- example, the genetic material of humans and nique called optical other eukaryotes (organisms that have a trapping to track RNA nucleus) includes a lot of DNA that doesn’t polymerase as it inches encode proteins. Some of this DNA is stuck right along DNA. Block and in the middle of genes. his team performed To distinguish the two types of DNA, scien- this work by designing tists call the coding sequences of genes exons and a specialized microscope the pieces in between introns (for intervening sensitive enough to watch the real-time motion of a single polymerase traveling down a gene on one chromosome. The researchers discovered that molecules of RNA polymerase behave like battery-powered spiders as they crawl along the DNA ladder, sequences). If RNA polymerase were to transcribe DNA from the start of an intron-containing gene to the end, the RNA would be complementary to the introns as well as the exons. To get an mRNA molecule that yields a work- adding nucleotides one at a time to the growing ing protein, the cell needs to trim out the intron RNA strand. The enzyme works much like a sections and then stitch only the exon pieces motor, Block believes, powered by energy released together (see drawing, page 15). This process is during the chemical synthesis of RNA. called RNA splicing. The New Genetics I How Genes Work 15 RNA Splicing Gene DNA Intron 1 Exon 1 Genes are often interrupted Exon 2 Intron 2 Exon 3 by stretches of DNA (introns, blue) that do not contain instructions for making a protein. The DNA segments that do contain protein-making instructions are known as exons (green). Transcription (RNA synthesis) Nuclear RNA Exon 1 Intron 1 Exon 2 Intron 2 Exon 3 RNA splicing Exon 1 Messenger RNA Exon 2 Exon 3 Translation (protein synthesis) Protein Gene DNA Exon 1 Exon 2 Exon 3 Exon 4 Exon 1 Exon 2 Exon 3 Exon 4 Alternative splicing Exon 1 Exon 2 Exon 3 Exon 1 Exon 2 Translation Protein A Protein B Exon 4 Arranging exons in different patterns, called alternative splicing, enables cells to make different proteins from a single gene. 16 National Institute of General Medical Sciences Splicing has to be extremely accurate. An By cutting and pasting the exons in different error in the splicing process, even one that results patterns, which scientists call alternative splicing, in the deletion of just one nucleotide in an exon a cell can create different proteins from a single or the addition of just one nucleotide in an gene. Alternative splicing is one of the reasons intron, will throw the whole sequence out of why human cells, which have about 20,000 alignment. The result is usually an abnormal genes, can make hundreds of thousands of protein—or no protein at all. One form of different proteins. Alzheimer’s disease, for example, is caused by this kind of splicing error. Molecular biologist Christine Guthrie of the University of California, San Francisco, wants to understand more fully the mechanism for removing intron RNA and find out how it stays so accurate. She uses yeast cells for these experiments. Just like human DNA, yeast DNA has introns, but they are fewer and simpler in structure and are therefore easier to study. Guthrie can identify which genes are required for splicing by finding abnormal yeast cells that mangle splicing. So why do introns exist, if they’re just going to be chopped out? Without introns, cells wouldn’t need to go through the splicing process and keep monitoring it to be sure it’s working right. As it turns out, splicing also makes it possible for cells to create more proteins. Think about all the exons in a gene. If a cell stitches together exons 1, 2 and 4, leaving out exon 3, the mRNA will specify the production of a particular protein. But instead, if the cell stitches together exons 1, 2 and 3, this time leaving out exon 4, then the mRNA will be translated into a different protein (see drawing, page 15). All Together Now Until recently, researchers looked at genes, and the proteins they encode, one at a time. Now, they can look at how large numbers of genes and proteins act, as well as how they interact. This gives them a much better picture of what goes on in a living organism. Already, scientists can identify all of the genes that are transcribed in a cell—or in an organ, like the heart. And although researchers can’t tell you, right now, what’s going on in every cell of your body while you read a book or walk down the street, they can do this sort of “whole-body” scan for simpler, single-celled organisms like yeast. Using a technique called genome-wide location analysis, Richard Young of the Massachusetts Institute of Technology unraveled a “regulatory code” of living yeast cells, which have more than 6,000 genes in their genome. Young’s technique enabled him to determine the exact places where RNA polymerase’s helper proteins sit on DNA and tell RNA polymerase to begin transcribing a gene. Since he did the experiment with the yeast exposed to a variety of different conditions, The New Genetics I How Genes Work 17 GENETICS AND YOU: W Nursery Genetics hile most genetic research Newborn screening is governed by uses lab organisms, test individual states. This means that the tubes and petri dishes, state in which a baby the results have real consequences for is born determines the people. Your first encounter with genetic conditions for genetic analysis probably happened which he or she will be shortly after you were born, when a screened. Currently, doctor or nurse took a drop of blood states test for between from the heel of your tiny foot. 28 and 54 conditions. All states test Lab tests performed with that single drop of blood can diagnose certain rare for PKU. Although expanded screening for genetic disorders as well as metabolic genetic diseases in newborns is advo- problems like phenylketonuria (PKU). cated by some, others question the Screening newborns in this way value of screening for conditions that began in the 1960s in Massachusetts are currently untreatable. Another with testing for PKU, a disease affecting issue is that some children with mild 1 in 14,000 people. PKU is caused by an versions of certain genetic diseases enzyme that doesn’t work properly due may be treated needlessly. to a genetic muta- In 2006, the Advisory Committee tion. Those born on Heritable Disorders in Newborns with this disorder and Children, which assists the Secretary cannot metabolize of the U.S. Department of Health and the amino acid Human Services, recommended a phenylalanine, standard, national set of newborn which is present tests for 29 conditions, ranging from in many foods. Left untreated, PKU can relatively common hearing problems lead to mental retardation and neurolog- to very rare metabolic diseases. ical damage, but a special diet can prevent these outcomes. Testing for this condition has made a huge difference in many lives. 18 National Institute of General Medical Sciences Young was able to figure out how transcription method to scan the entire human genome in patterns differ when the yeast cell is under stress small samples of cells taken from the pancreases (say, in a dry environment) or thriving in a sugary- and livers of people with type 2 diabetes. He rich nutrient solution. Done one gene at a time, used the results to identify genes that aren’t tran- using methods considered state-of-the-art just a scribed correctly in people with the disease. few years ago, this kind of analysis would have taken hundreds of years. After demonstrating that his technique This information provides researchers with an important tool for understanding how diabetes and other diseases are influenced by worked in yeast, Young then took his research defective genes. By building models to predict a step forward. He used a variation of the yeast how genes respond in diverse situations, researchers may be able to learn how to stop or jump-start genes on demand, change the course of a disease or prevent it from ever happening. Found in Translation After a gene has been read by RNA polymerase and the RNA is spliced, what happens next in the journey from gene to protein? The next step is reading the RNA information and fitting the building blocks of a protein together. This is called translation, and its principal actors are the ribosome and amino acids. Ribosomes are among the biggest and most intricate structures in the cell. The ribosomes of bacteria contain not only huge amounts of RNA, but also more than 50 different proteins. Human ribosomes have even more RNA and between 70 and 80 different proteins! Harry Noller of the University of California, A ribosome consists of large and small protein subunits with transfer RNAs nestled in the middle. RIBOSOME STRUCTURE COURTESY OF JAMIE CATE, MARAT YUSUPOV, Santa Cruz, has found that a ribosome performs several key jobs when it translates the genetic code of mRNA. As the messenger RNA threads GULNARA YUSUPOVA, THOMAS EARNEST AND HARRY NOLLER. GRAPHIC COURTESY OF ALBION BAUCOM, UNIVERSITY OF CALIFORNIA, SANTA CRUZ. through the ribosome protein machine, the The New Genetics I How Genes Work 19 ribosome reads the mRNA sequence and helps recognize and recruit the correct amino acidcarrying transfer RNA to match the mRNA code. The ribosome also links each additional amino acid into a growing protein chain (see drawing, page 13). For many years, researchers believed that even though RNAs formed a part of the ribosome, the protein portion of the ribosome did all of the work. Noller thought, instead, that maybe RNA, not proteins, performed the ribosome’s job. His Some first-aid ointments contain the antibiotic neomycin, which treats infections by attacking ribosomes in bacteria. idea was not popular at first, because at that time it was thought that RNA could not perform such RNA Surprises complex functions. But which ribosomal RNAs are doing the work? Some time later, however, the consensus Most scientists assumed that RNA nucleotides changed. Sidney Altman of Yale University in buried deep within the ribosome complex—the New Haven, Connecticut, and Thomas Cech, ones that have the same sequence in every species who was then at the University of Colorado in from bacteria to people—were the important Boulder, each discovered that RNA can perform ones for piecing the growing protein together. work as complex as that done by protein enzymes. However, recent research by Rachel Green, Their “RNA-as-an-enzyme” discovery turned the who worked with Noller before moving research world on its head and earned Cech and to Johns Hopkins University in Baltimore, Altman the 1989 Nobel Prize in chemistry. Maryland, showed that this is not the case. Noller and other researchers have continued Green discovered that those RNA nucleotides the painstaking work of understanding ribo- are not needed for assembling a protein. Instead, somes. In 1999, he showed how different parts she found, the nucleotides do something else of a bacterial ribosome interact with one entirely: They help the growing protein slip off another and how the ribosome interacts with the ribosome once it’s finished. molecules involved in protein synthesis. Noller, Green and hundreds of other scientists These studies provided near proof that the work with the ribosomes of bacteria. Why should fundamental mechanism of translation is you care about how bacteria create proteins from performed by RNA, not by the proteins of their genes? the ribosome. 20 National Institute of General Medical Sciences One reason is that this knowledge is impor- An Interesting Development tant for learning how to disrupt the actions of In the human body, one of the most important disease-causing microorganisms. For example, jobs for proteins is to control how embryos antibiotics like erythromycin and neomycin work develop. Scientists discovered a hugely important by attacking the ribosomes of bacteria, which are set of proteins involved in development by study- different enough from human ribosomes that our ing mutations that cause bizarre malformations cells are not affected by these drugs. in fruit flies. As researchers gain new information about The most famous such abnormality is a fruit bacterial translation, the knowledge may lead to fly with a leg, rather than the usual antenna, more antibiotics for people. growing out of its head (see page 21). According New antibiotics are urgently needed because to Thomas C. Kaufman of Indiana University many bacteria have developed resistance to the in Bloomington, the leg is perfectly normal—it’s current arsenal. This resistance is sometimes the just growing in the wrong place. result of changes in the bacteria’s ribosomal RNA. In this type of mutation and many others, It can be difficult to find those small, but critical, something goes wrong with the genetic program changes that may lead to resistance, so it is that directs some of the cells in an embryo to important to find completely new ways to block follow developmental pathways, which are bacterial translation. a series of chemical reactions that occur in a Green is working on that problem too. Her specific order. In the antenna-into-leg problem, strategy is to make random mutations to the it is as if the cells growing from the fly’s head, genes in a bacterium that affect its ribosomes. which normally would become an antenna, But what if the mutation disables the ribosome mistakenly believe that they are in the fly’s so much that it can’t make proteins? Then the thorax, and therefore ought to grow into a leg. bacterium won’t grow, and Green wouldn’t find it. And so they do. Using clever molecular tricks, Green figured Thinking about this odd situation taught out a way to rescue some of the bacteria with scientists an important lesson—that the proteins defective ribosomes so they could grow. While made by some genes can act as switches. Switch some of the rescued bacteria have changes in genes are master controllers that provide each their ribosomal RNA that make them resistant body part with a kind of identification card. If a to certain antibiotics (and thus would not make protein that normally instructs cells to become good antibiotic targets) other RNA changes that an antenna is disrupted, cells can receive new don’t affect resistance may point to promising instructions to become a leg instead. ideas for new antibiotics. The New Genetics I How Genes Work 21 FLYBASE; R. TURNER Normal fruit fly head. Fruit fly head showing the effects of the Antennapedia gene. This fly has legs where its antennae should be. Scientists determined that several different genes of different organisms, it’s a good clue genes, each with a common sequence, provide that these genes do something so important and these anatomical identification card instructions. useful that evolution uses the same sequence Kaufman isolated and described one of these over and over and permits very few changes in genes, which became known as Antennapedia, its structure as new species evolve. a word that means “antenna feet.” Kaufman then began looking a lot more Researchers quickly discovered nearly identical versions of homeobox DNA in almost closely at the molecular structure of the every non-bacterial cell they examined—from Antennapedia gene. In the early 1980s, he and yeast to plants, frogs, worms, beetles, chickens, other researchers made a discovery that has been mice and people. fundamental to understanding evolution as well as developmental biology. The scientists found a short sequence of DNA, Hundreds of homeobox-containing genes have been identified, and the proteins they make turn out to be involved in the early stages now called the homeobox, that is present not only of development of many species. For example, in Antennapedia but in the several genes next to researchers have found that abnormalities in it and in genes in many other organisms. When the homeobox genes can lead to extra fingers or geneticists find very similar DNA sequences in the toes in humans. 22 National Institute of General Medical Sciences The Tools of Genetics: Mighty Microarrays We now have the ability to attach a piece of every but teachers and students are using them, too. gene in a genome (all of an organism’s genes) to The Genome Consortium for Active Teaching a postage stamp-sized glass microscope slide. program (www.bio.davidson.edu/GCAT) pro- This ordered series of DNA spots is called a DNA vides resources and instructions for high school microarray, a gene chip or a DNA chip. and college students to do gene-chip experiments Whichever name you prefer, the chip could also be called revolutionary. This technology has in class. Microarrays are used to get clues about changed the way many geneticists do their work which genes are expressed to control cell, tissue by making it possible to observe the activity of or organ function. By measuring the level of RNA thousands of genes at once. production for every gene at the same time, In recent years, microarrays have become standard equipment for modern biologists, researchers can learn the genetic programming that makes cell types different and diseased cells different from healthy ones. The chips consist of large numbers of DNA fragments distributed in rows in a very small space. The arrays are laid out by robots that can DNA fragments DNA fragments are attached to glass or plastic, then fluorescently tagged molecules are washed over the fragments. Complementary mRNA Some molecules (green) bind to their complementary sequence. These molecules can be identified because they glow under fluorescent light. The resulting pattern of fluorescence indicates which genes are active. Got It? Why are some infections hard to treat with antibiotics? What are some things researchers might do to solve this public health problem? position DNA fragments so precisely that In December 2004, the U.S. Food and more than 20,000 of them can fit on one micro- Drug Administration cleared the first scope slide. gene chip for medical use. The Amplichip Scientists isolate mRNA from cells grown CYP450™, made by Roche Molecular Systems under two conditions and tag the two sources Inc. of Pleasanton, California, analyzes varia- of RNA with different colors of fluorescent mole- tions in two genes that play a major role in cules. The two colors of RNA are then placed the body’s processing of many widely pre- on the chip, where they attach to complementary scribed drugs. This information can help DNA fragments anchored to the chip’s surface. doctors choose the proper dose of certain Next, a scanner measures the amount of fluorescence at each spot on the chip, revealing how active each gene was (how much mRNA each gene produced). A computer analyzes the patterns of gene activity, providing a snapshot of a genome under two conditions (e.g., healthy or diseased). medicines for an individual patient. How does DNA work as a form of information storage? How can 20,000 human genes provide the instructions for making hundreds of thousands of different proteins? What newborn tests does your area hospital routinely do? CHAPTER 2 RNA and DNA Revealed: New Roles, New Rules F or many years, when scientists thought about heredity, DNA was the first thing to come to mind. It’s true that DNA is the basic ingredient of our genes and, as such, it often C steals the limelight from RNA, the other form G of genetic material inside our cells. U C But, while they are both types of genetic Sugarphosphate backbone U material, RNA and DNA are rather different. C G The chemical units of RNA are like those of A DNA, except that RNA has the nucleotide uracil C (U) instead of thymine (T). Unlike double- U C stranded DNA, RNA usually comes as only a single G strand. And the nucleotides in RNA contain ribose G A sugar molecules in place of deoxyribose. U RNA is quite flexible—unlike DNA, which is Base U a rigid, spiral-staircase molecule that is very stable. G C RNA can twist itself into a variety of complicated, U three-dimensional shapes. RNA is also unstable in C that cells constantly break it down and must conC tinually make it fresh, while DNA is not broken A down often. RNA’s instability lets cells change G C their patterns of protein synthesis very quickly A in response to what’s going on around them. Many textbooks still portray RNA as a passive molecule, simply a “middle step” in the cell’s gene-reading activities. But that view is no longer accurate. Each year, researchers unlock new C A U ៌ Ribonucleic acid (RNA) has the bases adenine (A), cytosine (C), guanine (G) and uracil (U). secrets about RNA. These discoveries reveal that it is truly a remarkable molecule and a multi talented actor in heredity. RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA The New Genetics I RNA and DNA Revealed: New Roles, New Rules 25 ៊ Riboswitches are RNA RONALD BREAKER sequences that control gene activity. The riboswitch shown here bends into a special shape when it grips tightly onto a molecule called a metabolite (colored balls) that bacteria need to survive. Today, many scientists believe that RNA because of its ability to lead a double life: to store evolved on the Earth long before DNA did. information and to conduct chemical reactions. Researchers hypothesize — obviously, no one In other words, in this world, RNA served the was around to write this down — that RNA was functions of both DNA and proteins. a major participant in the chemical reactions that ultimately spawned the first signs of life on the planet. What does any of this have to do with human health? Plenty, it turns out. Today’s researchers are harnessing some of RNA’s flexibility and power. For example, through RNA World At least two basic requirements exist for making a cell: the ability to hook molecules together and break them apart, and the ability to replicate, or copy itself, from existing information. RNA probably helped to form the first cell. The first organic molecules, meaning molecules containing carbon, most likely arose out of random collisions of gases in the Earth’s primitive atmosphere, energy from the Sun, and heat from naturally occurring radioactivity. Some scientists think that a strategy he calls directed evolution, molecular engineer Ronald R. Breaker of Yale University is developing ways to create entirely new forms of RNA and DNA that both work as enzymes. Breaker and others have also uncovered a hidden world of RNAs that play a major role in controlling gene activity, a job once thought to be performed exclusively by proteins. These RNAs, which the scientists named riboswitches, are found in a wide variety of bacteria and other organisms. in this primitive world, RNA was a critical molecule RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA 26 National Institute of General Medical Sciences This discovery has led Breaker to speculate that new kinds of antibiotic medicines could be developed to target bacterial riboswitches. Molecular Editor Scientists are learning of another way to customize proteins: by RNA editing. Although DNA sequences spell out instructions for producing ៉ RNA comes in a variety of different shapes (above and right). RNA and proteins, these instructions aren’t always followed precisely. Editing a gene’s mRNA, even by a single chemical letter, can radically change ៊ Double-stranded DNA the resulting protein’s function. (left) is a staircase-like molecule. Nature likely evolved the RNA editing function as a way to get more proteins out of the same number of Small But Powerful Larger RNA Dicer enzyme MicroRNA mRNA Near-perfect complementarity to target mRNA Recently, molecules called microRNAs have been found in organisms as diverse as plants, worms and people. The molecules are truly “micro,” consisting of only a few dozen nucleotides, compared to typical human mRNAs that are a few thousand nucleotides long. What’s particularly interesting about microRNAs is that many of them arise from DNA that used to be considered merely filler material (see page 14). How do these small but important RNA molecules do their work? They start out much bigger but get trimmed by cellular enzymes, including one aptly named Dicer. Like tiny pieces of ៊ The enzyme Dicer generates microRNAs by No translation No protein chopping larger RNA molecules into tiny Velcro®-like pieces. MicroRNAs stick to mRNA molecules and prevent the mRNAs from being made into proteins. RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA The New Genetics I RNA and DNA Revealed: New Roles, New Rules 27 genes. For example, researchers have found that the RNA sequence, which in turn changes the the mRNAs for certain proteins important for the protein that gets made. proper functioning of the nervous system are Bass’ experiments show that RNA editing particularly prone to editing. It may be that RNA occurs in a variety of organisms, including peo- editing gives certain brain cells the capacity to ple. Another interesting aspect of editing is that react quickly to a changing environment. certain disease-causing microorganisms, such as Which molecules serve as the editor and how some forms of parasites, use RNA editing to gain does this happen? Brenda Bass of the University of a survival edge when living in a human host. Utah School of Medicine in Salt Lake City studies Understanding the details of this process is an one particular class of editors called adenosine important area of medical research. deaminases. These enzymes “retype” RNA letters at various places within an mRNA transcript. They do their job by searching for characteristic RNA shapes. Telltale twists and bends in folded RNA molecules signal these enzymes to change AMY PASQUINELLI Velcro®, microRNAs stick to certain mRNA molecules and stop them from passing on their protein-making instructions. First discovered in a roundworm model system (see Living Laboratories, page 49), some microRNAs help determine the organism’s body plan. In their absence, very bad things can happen. For example, worms engineered to lack a microRNA called let-7 develop so abnormally that they often rupture and practically break in half as the worm grows. Perhaps it is not surprising that since microRNAs help specify the timing of an organism’s developmental plan, the appearance of the microRNAs themselves is carefully timed inside a developing organism. Biologists, including Amy Pasquinelli of the University of California, San Diego, are currently figuring out how microRNAs are made and cut to size, as well as how they are produced at the proper time during development. ៌ Worms with a mutated form of the microRNA let-7 (right) have severe growth problems, rupturing as they develop. MicroRNA molecules also have been linked to cancer. For example, Gregory Hannon of the Cold Spring Harbor Laboratory on Long Island, New York, found that certain microRNAs are associated with the severity of the blood cancer B-cell lymphoma in mice. Since the discovery of microRNAs in the first years of the 21st century, scientists have identified hundreds of them that likely exist as part of a large family with similar nucleotide sequences. New roles for these molecules are still being found. RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA 28 National Institute of General Medical Sciences RNA Interference (RNAi) Dicer enzyme ៊ Double-stranded RNA (dsRNA) is chopped dsRNA into short interfering RNAs (siRNAs) by the enzyme Dicer. Short interfering RNAs (siRNAs) A U C G U A C G RISC A ៉ The RNA-induced silencing U complex (RISC) enzyme attaches to siRNA. ៉ The siRNA-RISC complex U C A G G U C A A C U G G C mRNA attaches to target mRNA and chops the mRNA into small pieces. Chopped mRNA (no longer functional) RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA The New Genetics I RNA and DNA Revealed: New Roles, New Rules 29 Healthy Interference RNA controls genes in a way that was only discovered recently: a process called RNA interference, or RNAi. Although scientists identified RNAi less than 10 years ago, they now know that organisms have been using this trick for millions of years. Researchers believe that RNAi arose as a way to of genes that affect cell growth and tissue reduce the production of a gene’s encoded protein formation in roundworms, using a molecular for purposes of fine-tuning growth or self-defense. tool called antisense RNA. When viruses infect cells, for example, they com- To their surprise, Mello and Fire found mand their host to produce specialized RNAs that their antisense RNA tool wasn’t doing that allow the virus to survive and make copies much at all. Rather, they determined, a double- of itself. Researchers believe that RNAi eliminates stranded contaminant produced during the unwanted viral RNA, and some speculate that synthesis of the single-stranded antisense RNA it may even play a role in human immunity. interfered with gene expression. Mello and Oddly enough, scientists discovered RNAi Fire named the process RNAi, and in 2006 were from a failed experiment! Researchers investi- awarded the Nobel Prize in physiology or gating genes involved in plant growth noticed medicine for their discovery. something strange: When they tried to turn Further experiments revealed that the double- petunia flowers purple by adding an extra stranded RNA gets chopped up inside the cell “purple” gene, the flowers bloomed white instead. into much smaller pieces that stick to mRNA and This result fascinated researchers, who could not understand how adding genetic material could somehow get rid of an inherited trait. The block its action, much like the microRNA pieces of Velcro discussed above (see drawing, page 28). Today, scientists are taking a cue from nature mystery remained unsolved until, a few years and using RNAi to explore biology. They have later, two geneticists studying development saw learned, for example, that the process is not limited a similar thing happening in lab animals. to worms and plants, but operates in humans too. The researchers, Andrew Z. Fire, then of the Medical researchers are currently testing new Carnegie Institution of Washington in Baltimore types of RNAi-based drugs for treating condi- and now at Stanford University, and Craig Mello tions such as macular degeneration, the leading of the University of Massachusetts Medical School cause of blindness, and various infections, includ- in Worcester, were trying to block the expression ing those caused by HIV and the herpes virus. RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA RNA 30 National Institute of General Medical Sciences DNA ៉ Histone proteins loop together with double-stranded DNA to form a structure that resembles beads on a string. Histones Chromatin Dynamic DNA without changing its sequence. These changes A good part of who we are is “written in our make genes either more or less likely to be genes,” inherited from Mom and Dad. Many expressed (see drawing, page 31). traits, like red or brown hair, body shape and Currently, scientists are following an intrigu- even some personality quirks, are passed on from ing course of discovery to identify epigenetic parent to offspring. factors that, along with diet and other environ- But genes are not the whole story. Where we live, how much we exercise, what we eat: These mental influences, affect who we are and what type of illnesses we might get. and many other environmental factors can all affect how our genes get expressed. You know that changes in DNA and RNA can produce changes in proteins. But additional control happens at the level of DNA, even though these changes do not alter DNA directly. Inherited factors that do not change the DNA sequence of nucleotides are called epigenetic changes, and they too help make each of us unique. Epigenetic means, literally, “upon” or “over” genetics. It describes a type of chemical reaction that can alter the physical properties of DNA Secret Code DNA is spooled up compactly inside cells in an arrangement called chromatin. This packaging is critical for DNA to do its work. Chromatin consists of long strings of DNA spooled around a compact assembly of proteins called histones. One of the key functions of chromatin is to control access to genes, since not all genes are turned on at the same time. Improper expression of growth-promoting genes, for example, can lead to cancer, birth defects or other health concerns. DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA The New Genetics I RNA and DNA Revealed: New Roles, New Rules 31 DNA Many years after the structure of DNA was determined, researchers used a powerful device known as an electron microscope to take pictures of chromatin fibers. Upon viewing chromatin up close, the researchers described it as “beads on a string,” an image still used today. The beads were the histone balls, and the string was DNA wrapped around the histones and connecting one bead to the next. Decades of study eventually revealed that histones have special chemical tags that act like switches to control access to the DNA. Flipping these switches, called epigenetic markings, unwinds the spooled DNA so the Histone tails genes can be transcribed. The observation that a cell’s gene-reading machinery tracks epigenetic markings led Histones C. David Allis, who was then at the University of Virginia Health Sciences Center in Charlottesville and now works at the Chromosome Rockefeller University in New York City, to coin a new phrase, the “histone code.” He and others believe that the histone code plays a major role in determining which proteins get made in a cell. Flaws in the histone code have been associated with several types of cancer, and researchers are actively pursuing the development of medicines to correct such errors. ៌ The “epigenetic code” controls gene activity with chemical tags that mark DNA (purple diamonds) and the “tails” of histone proteins (purple triangles). These markings help determine whether genes will be transcribed by RNA polymerase. Genes hidden from access to RNA polymerase are not expressed. DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA 32 National Institute of General Medical Sciences GENETICS AND YOU: O The Genetics of Anticipation ccasionally, unusual factors influence whether or not a child will be born with a The number of triplet repeats seems to increase as the chromosome is passed down through several generations. Thus, the grandsons of a man genetic disease. An example is the molecular error with a fragile X chromosome, who is that causes Fragile X syndrome, a rare not himself affected, have a 40 percent condition associated with mental retar- risk of retardation if they inherit the dation. The mutation leading to a fragile repeat-containing chromosome. The X chromosome is not a typical DNA typ- risk for great-grandsons is even higher: ing mistake, in which nucleotides are 50 percent. switched around or dropped, or one of Intrigued by the evidence that triplet them is switched for repeats can cause genetic disease, scien- another nucleotide. tists have searched for other examples Instead, it is a kind of disorders associated with the DNA of stutter by the DNA expansions. To date, more than a dozen polymerase enzyme such disorders have been found, and all that copies DNA. This of them affect the nervous system. stutter creates a string of repeats of a Analysis of the rare families in DNA sequence that is composed of just which such diseases are common has three nucleotides, CGG. revealed that expansion of the triplet Some people have only one repeat repeats is linked to something called of the CGG nucleotide triplet. Thus, they genetic anticipation, when a disease’s have two copies of the repeat in a gene, symptoms appear earlier and more and the extra sequence reads CGGCGG. severely in each successive generation. Others have more than a thousand copies of the repeat. These people are the most severely affected. DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA The New Genetics I RNA and DNA Revealed: New Roles, New Rules 33 ៊ Igf2 is an imprinted gene. A Normal Igf2 gene variant (expressed) single copy of the abnormal, or mutant, form of the Igf2 gene (red) causes growth defects, but only if the abnormal gene variant is inherited from the father. Paternal Maternal Mutant Igf2 gene variant (not expressed) Normal size mouse Mutant Igf2 gene variant (expressed) Paternal Maternal Dwarf mouse Normal Igf2 gene variant (not expressed) Battle of the Sexes father’s copy of Igf2 is expressed, and the mother’s A process called imprinting, which occurs natu- copy remains silent (is not expressed) throughout rally in our cells, provides another example of the life of the offspring. how epigenetics affects gene activity. With most genes, the two copies work exactly Scientists have discovered that this selective silencing of Igf2 and many other imprinted genes the same way. For some mammalian genes, how- occurs in all placental mammals (all except the ever, only the mother’s or the father’s copy is platypus, echidna and marsupials) examined switched on regardless of the child’s gender. This so far, but not in birds. is because the genes are chemically marked, or Why would nature tolerate a process that puts imprinted, during the process that generates eggs an organism at risk because only one of two and sperm. copies of a gene is working? The likely reason, As a result, the embryo that emerges from the many researchers believe, is that mothers and joining of egg and sperm can tell whether a gene fathers have competing interests, and the battle- copy came from Mom or Dad, so it knows which field is DNA! copy of the gene to shut off. One example of an imprinted gene is insulin- The scenario goes like this: It is in a father’s interest for his embryos to get bigger faster, like growth factor 2 (Igf2), a gene that helps a because that will improve his offspring’s chances mammalian fetus grow. In this case, only the of survival after birth. The better an individual’s DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA 34 National Institute of General Medical Sciences chance of surviving infancy, the better its chance Starting at the End of becoming an adult, mating and passing its When we think of DNA, we think of genes. genes on to the next generation. However, some DNA sequences are different: Of course mothers want strong babies, but unlike fathers, mothers provide physical resources They don’t encode RNAs or proteins. Introns, described in Chapter 1, are in this category. to embryos during pregnancy. Over her lifetime, Another example is telomeres—the ends of a female is likely to be pregnant several times, so chromosomes. There are no genes in telomeres, she needs to divide her resources among a num- but they serve an essential function. Like ber of embryos in different pregnancies. shoelaces without their tips, chromosomes with- Researchers have discovered over 200 imprinted out telomeres unravel and fray. And without genes in mammals since the first one was identified telomeres, chromosomes stick to each other and in 1991. We now know that imprinting controls cause cells to undergo harmful changes like divid- some of the genes that have an important role in ing abnormally. regulating embryonic and fetal growth and allocat- Researchers know a good deal about telo- ing maternal resources. Not surprisingly, mutations meres, dating back to experiments performed in these genes cause serious growth disorders. in the 1970s by Elizabeth Blackburn, a basic Marisa Bartolomei of the University of Pennsylvania School of Medicine in Philadelphia researcher who was curious about some of the fundamental events that take place within cells. is trying to figure out how Igf2 and other genes become imprinted and stay silent throughout the life of an individual. She has already identified sequences within genes that are essential for imprinting. Bartolomei and other researchers have shown that these sequences, called insulators, serve as “landing sites” for a protein that keeps the imprinted gene from being transcribed. tips of chromosomes, appear white in this photo. HESED PADILLA-NASH AND THOMAS RIED ៉ Telomeres, repeated nucleotide sequences at the DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA The New Genetics I RNA and DNA Revealed: New Roles, New Rules 35 At the time, Blackburn, now at the University of California, San Francisco, was working with Joseph Gall at Yale University. For her experimental system, she chose a single-celled, CAROL GREIDER pond-dwelling organism named Tetrahymena. These tiny, pear-shaped creatures are covered with hairlike cilia that they use to propel themselves through the water as they devour bacteria and fungi. Tetrahymena was a good organism for ៌ Molecular biologist Carol Greider discovered the enzyme telomerase. This license plate, which was on her car when she worked at Cold Spring Harbor Laboratory on Long Island, New York, advertises her research interest! Blackburn’s experiments because it has a large number of chromosomes—which means it has a lot of telomeres! Her research was also perfectly timed, because an enzyme that added copies of the repeated methods for sequencing DNA were just being sequence to the telomeres of some but not all developed. Blackburn found that Tetrahymena’s chromosomes. telomeres had an unusual nucleotide sequence: With her then-graduate student Carol TTGGGG, repeated about 50 times per telomere. Greider, now at Johns Hopkins University, Since then, scientists have discovered that the Blackburn hunted for the enzyme. The team telomeres of almost all organisms have repeated found it and Greider named it telomerase. sequences of DNA with lots of Ts and Gs. In Blackburn, Greider and Jack Szostak of Harvard human and mouse telomeres, for example, the Medical School in Boston shared the 2009 Nobel repeated sequence is TTAGGG. Prize in physiology or medicine for their discov- The number of telomere repeats varies enormously, not just from organism to organism but eries about telomeres and telomerase. As it turns out, the telomerase enzyme con- in different cells of the same organism and even sists of a protein and an RNA component, which within a single cell over time. Blackburn reasoned the enzyme uses as a template for copying the that the repeat number might vary if cells had repeated DNA sequence. DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA 36 National Institute of General Medical Sciences What is the natural function of telomerase? The Other Human Genome As cells divide again and again, their telomeres Before you think everything’s been said about get shorter. Most normal cells stop dividing when DNA, there’s one little thing we didn’t mention: their telomeres wear down to a certain point, and Some of the DNA in every cell is quite different eventually the cells die. Telomerase can counter- from the DNA that we’ve been talking about up act the shortening. By adding DNA to telomeres, to this point. This special DNA isn’t in chromo- telomerase rebuilds the telomere and resets the somes—it isn’t even inside the cell’s nucleus cell’s molecular clock. where all the chromosomes are! The discovery of telomerase triggered new So where is this special DNA? It’s inside mito- ideas and literally thousands of new studies. chondria, the organelles in our cells that produce Many researchers thought that the enzyme the energy-rich molecule adenosine triphosphate, might play important roles in cancer and aging. or ATP. Mendel knew nothing of mitochondria, Researchers were hoping to find ways to turn since they weren’t discovered until late in the telomerase on so that cells would continue to 19th century. And it wasn’t until the 1960s that divide (to grow extra cells for burn patients, researchers discovered the mitochondrial genome, for example), or off so that cells would stop which is circular like the genomes of bacteria. dividing (to stop cancer, for instance). So far, they have been unsuccessful. Although In human cells, mitochondrial DNA makes up less than 1 percent of the total DNA in each it is clear that telomerase and cellular aging are of our cells. The mitochondrial genome is very related, researchers do not know whether telo- small—containing only about three dozen genes. merase plays a role in the normal cellular aging These encode a few of the proteins that are in the process or in diseases like cancer. mitochondrion, plus a set of ribosomal RNAs Recently, however, Blackburn and a team of used for synthesizing proteins for the organelle. other scientists discovered that chronic stress and Mitochondria need many more proteins the perception that life is stressful affect telomere though, and most of these are encoded by genes length and telomerase activity in the cells of in the nucleus. Thus, the energy-producing capa- healthy women. Blackburn and her coworkers bilities of human mitochondria—a vital part of are currently conducting a long-term, follow-up any cell’s everyday health—depend on coordi- study to confirm these intriguing results. nated teamwork among hundreds of genes in two cellular neighborhoods: the nucleus and the mitochondrion. DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA The New Genetics I RNA and DNA Revealed: New Roles, New Rules 37 ៊ Mitochondria (labeled Mitochondrial DNA gets transcribed and with a red dye) are scattered throughout the cytoplasm of this human cancer cell. the RNA is translated by enzymes that are very different from those that perform this job for genes in our chromosomes. Mitochondrial enzymes look and act much more like those from bacteria, which is not surprising because mitochondria are thought to have descended from free-living bacteria that were engulfed by another cell over a billion years ago. Scientists have linked mitochondrial DNA ៊ The cell has also been defects with a wide range of age-related diseases treated with a dye that colors the mitochondrial DNA green. including neurodegenerative disorders, some forms of heart disease, diabetes and various cancers. It is still unclear, though, whether damaged mitochondria are a symptom or a cause of these health conditions. Scientists have studied mitochondrial DNA for another reason: to understand the history of the human race. Unlike our chromosomal DNA, which we inherit from both parents, we get all ៊ A computerized overlay of our mitochondrial DNA from our mothers. of these two images of the same cell shows that mitochondria and its DNA appear together (yellow regions). Thus, it is possible to deduce who our maternal ancestors were by tracking the inheritance of mutations in mitochondrial DNA. For reasons that are still not well understood, mutations accumulate in mitochondrial DNA more quickly than in chromosomal DNA. So, it’s possible to trace your maternal ancestry way back beyond way back to “African Eve,” the ancestor of us all! ALISON DAVIS any relatives you may know by name—all the DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA DNA 38 National Institute of General Medical Sciences The Tools of Genetics: Recombinant DNA and Cloning E. coli bacteria, taken from human intestine Nucleus Human cell Plasmid E. coli chromosome Strand of DNA from human cell Plasmid removed from E. coli Human DNA cut into pieces by restriction enzyme Plasmid cut open by restriction enzyme at a specific site ៉ Recombinant DNA. To splice a human gene (in this case, the one for insulin) into a plasmid, scientists take the plasmid out of an E. coli bacterium, cut the plasmid with a restriction enzyme and splice in insulin-making human DNA. The resulting hybrid plasmid can be inserted into another E. coli bacterium, where it multiplies along with the bacterium. There, it can produce large quantities of insulin. Human insulin gene Two pieces spliced together Recombinant DNA (hybrid plasmid) Human insulin gene Human plasmid inserted into E. coli cell Bacteria with hybrid plasmid replicate, creating clone capable of producing human insulin ROSLIN INSTITUTE, EDINBURGH ៊ Scientists in Scotland were the first to clone an animal, this sheep named Dolly. She later gave birth to Bonnie, the lamb next to her. In the early 1970s, scientists sequence. Most restriction endo- discovered that they could nucleases make slightly staggered change an organism’s genetic incisions, resulting in “sticky ends,” traits by putting genetic out of which one strand protrudes. material from another organ- The next step in this example is ism into its cells. This discovery, which caused to splice, or paste, the human insulin gene into quite a stir, paved the way for many extraordinary a circle of bacterial DNA called a plasmid. accomplishments in medical research that have Attaching the cut ends together is done with occurred over the past 35 years. a different enzyme (obtained from a virus), How do scientists move genes from one called DNA ligase. The sticky ends join back organism to another? The cutting and pasting together kind of like jigsaw puzzle pieces. The gets done with chemical scissors: enzymes, to be result: a cut-and-pasted mixture of human specific. Take insulin, for example. Let’s say a sci- and bacterial DNA. entist wants to make large quantities of this The last step is putting the new, recombi- protein to treat diabetes. She decides to transfer nant DNA back into E. coli and letting the the human gene for insulin into a bacterium, bacteria reproduce in a petri dish. Now, the Escherichia coli, or E. coli, which is commonly scientist has a great tool: a version of E. coli used for genetic research (see Living Laboratories, that produces lots of human insulin that can page 46). That’s because E. coli reproduces really be used for treating people with diabetes. fast, so after one bacterium gets the human Got It? Besides the sequence of nucleotides in genes, what are some other changes to DNA and RNA that can affect our health and who we are? Can you imagine treatments—other than vaccines and current medicines—crafted from genetic information and new molecular tools? So, what is cloning? Strictly speaking, it’s insulin gene, it doesn’t take much time to grow making many copies. However, the term is millions of bacteria that contain the gene. more commonly used to refer to making How is cloning a gene many copies of a gene, as in the E. coli different from cloning an a copied, or “cloned,” version of the human DNA example above. Researchers can also clone animal or a person? How using a special bacterial enzyme from bacteria entire organisms, like Dolly the sheep, which do researchers use gene called a restriction endonuclease. (The normal role contained the identical genetic material of cloning to study health of these enzymes in bacteria is to chew up the another sheep. and disease? The first step is to cut the insulin gene out of DNA of viruses and other invaders.) Each restriction enzyme recognizes and cuts at a different nucleotide sequence, so it’s possible to be very precise about DNA cutting by selecting one of several hundred of these enzymes that cuts at the desired Do you have any recurring illnesses in your extended family? Today CHAPTER 3 Life’s Genetic Tree I n all of biology, there is one thing that always stays the same. That thing, believe it or not, is change itself! The millions of different living things on Earth—plants, bacteria, insects, chimps, people and everything else—all came to be because of a process called biological evolution, in which organisms change over time. Time Because of biological evolution, early humans gained the ability to walk on two feet. Because of evolution, air-breathing whales can live in the ocean despite being mammals like us. Because of evolution, some bacteria can live in scalding water, others can survive in solid ice and still others can live deep in the Earth eating only rocks! Evolution happens every day, and it affects every species—including us. It changes entire populations, not individuals. And it has a big impact on medical research. Everything Evolves To understand evolution, let’s go back in time a century and a half to 1854, when the British naturalist Charles Darwin published The Origin First living species The New Genetics I Life’s Genetic Tree 41 Charles Darwin described evolution in his classic text, The Origin of Species. of Species, a book that proposed an explanation for how evolution works. The main concept in evolution is that all living things share a common ancestor. The very earliest ancestor of all life forms on Earth lived about 4 billion years ago. From that early organ- within a given generation will survive long ism, millions of types of creatures—some living enough to reproduce. and some now extinct—have evolved. Evolution requires diversity. You can tell that As an example, consider houseflies, each of which lays thousands of eggs every year. Why living things are diverse just by walking down the haven’t they taken over the world? Because street and looking around you. Individual people almost all of the baby houseflies die. The flies that are very different from one another. Chihuahuas survive are the ones that can find something to are different from Great Danes, and Siamese cats eat and drink … the ones that avoid being eaten, are different from tabbies. stepped on or swatted … and the ones that don’t Evolution also depends on inheritance. Many of our unique characteristics are inherited—they freeze, drown or land on a bug zapper. The flies that survive all these ways to die have are passed from parent to offspring. This is easy what it takes to outlive most of their brothers and to see: Dalmatian puppies look like Dalmatians, sisters. These inherited traits give an organism a not Chihuahuas. Petunias grow differently from survival edge. Those who survive will mate with pansies. Evolution works only on traits that are each other and will pass on to the next generation inherited. some of their DNA that encoded these advanta- Finally, as you probably already know, evolution favors the “fittest.” Through a process called natural selection, only some offspring geous traits. Of course, not all aspects of survival are determined by genes. Whether a fly gets swatted 42 National Institute of General Medical Sciences depends on genes that affect its reflexes—whether discovered a rare genetic variant that protects it’s fast enough to avoid the swatter— but also people from getting AIDS. A genetic variant is a on the environment. If there’s no human around different version of a gene, one that has a slightly waving the swatter, the fly is quite likely to sur- different sequence of nucleotides. vive, regardless of its reflexes. Evolution often takes a long time to make a Scientists think that the rare variant of a gene called CCR5 originally may have been selected difference. But it can also happen very quickly, during evolution because it made people resistant especially in organisms with short lifespans. For to an organism unrelated to HIV. example, as you read earlier, some bacteria have molecular features that let them survive in the presence of antibiotics. When you take an antibiotic medicine, antibiotic-resistant bacteria flourish while antibiotic-sensitive bacteria die. Because antibiotic resistance is a growing public health threat, it’s important to take the whole course of antibiotic medicine, not stop when you feel better. And you should take antibiotics only when they’re needed, not for colds or other viral infections, which antibiotics can’t treat. Montgomery Slatkin of the University of California, Berkeley, has used mathematical modeling techniques to show that natural selection over time could explain the frequency of the CCR5 variant in human populations. The work indicates that the CCR5 gene variant’s ability to protect against AIDS may contribute to keeping it in the human gene pool. So, through evolution, living things change. Sometimes, that’s good for us, as when humans understand HIV resistance in hopes of preventing AIDS. But sometimes the changes aren’t so great Selective Study —from a human perspective, anyway—as when Scientists doing medical research are very inter- bacteria become resistant to antibiotics. ested in genetic variants that have been selected by evolution. For example, researchers have Different nucleotides (in this example, A or G) can appear in the DNA sequence of the same chromosome from two different individuals, creating a single-nucleotide polymorphism (SNP). Whether the consequences of evolutionary change are good or bad, understanding the T C G A T A A T G C A T G C A T A One person’s DNA T C G A T A G T G C A T G C A T A Another person’s DNA The New Genetics I Life’s Genetic Tree 43 Haplotypes are combinaOriginal haplotype on chromosome T A T C A T 10,000 nucleotides Haplotype 1 C A T C A T T A T C A A T A T C C A C G T C A T Haplotype 2 Haplotype 3 Haplotype 4 process can help us develop new strategies for polymorphisms (abbreviated SNPs and pro- fighting disease. nounced “snips”). For example, let’s say that a certain nucleotide Clues from Variation Scientists know quite a bit about how cells reshuffle genetic information to create each person’s unique genome. But many details are missing about how this genetic variation contributes to disease, making for a very active area of research. What scientists do know is that most of the human genome is the same in all of us. A little bit of genetic variation—differences that account for much less than 1 percent of our DNA—gives each of us a unique personality, appearance and health profile. The parts of the human genome where the DNA sequences of many individuals vary by a single nucleotide are known as single-nucleotide in one of your genes is A. In your uncle, however, the nucleotide in the same place on the same gene might be G. You and your uncle have slightly different versions of that gene. Scientists call the different gene versions alleles. If two genes sit right next to each other on a chromosome, the SNPs in those genes tend to be inherited together. This set of neighboring SNPs is called a haplotype (see drawing above). Most chromosome regions have only a few, common haplotypes among all humans. As it turns out, these few haplotypes—in different combinations in each person—appear to account for most of the variation from person to person in a population. tions of gene variants, or SNPs, that are likely to be inherited together within the same chromosomal region. In this example, an original haplotype (top) evolved over time to create three newer haplotypes that each differ by a few nucleotides (red). 44 National Institute of General Medical Sciences Scientists can use haplotype information to compare the genes of people affected by a disease with those of unaffected people. For example, this approach revealed a genetic variation that substantially increases the risk of age-related macular degeneration, the leading cause of severe vision loss in the elderly. Scientists discovered that a single SNP—one nucleotide in the 3 billion-nucleotide human genome—makes some people more likely to get this eye disease. The discovery paves the way for better diagnostic tests and treatments. What about other diseases? In 2007, an international scientific team completed a catalog environments. He’s also curious about whether of common human haplotypes. Since then, it can create problems for some individuals. researchers have been using the catalog to identify You might be surprised to learn that genes associated with susceptibility to many com- Rieseberg’s principal research subject is the sun- mon diseases, including asthma, diabetes, cancer flower. Although many plants produce only one and heart disease. generation a year, plants like sunflowers can be But not all SNPs are in genes. Scientists study- very useful tools for researchers asking funda- ing genetic variation have also found SNPs in mental questions about genetics. Because their DNA that doesn’t encode proteins. Nonetheless, genetic material is more malleable than that of some of these SNPs appear to affect gene activity. many animals, plants are excellent models for Some researchers suspect that the “cryptic” (hidden) variation associated with SNPs in studying how evolution works. Wild sunflowers appealed to Rieseberg non-coding DNA plays an important role in because there are several species that live in determining the physical characteristics and different habitats. Two ancient species of wild behaviors of an organism. sunflowers grow in moderate climates and are Loren Rieseberg of Indiana University in Bloomington is one scientist who would love to take the mystery out of cryptic variation. He broadly distributed throughout the central and western United States. Three recently evolved sunflower species live wants to know how this non-coding genetic in more specialized environments: One of the variation can help organisms adapt to new new species grows on sand dunes, another grows The New Genetics I Life’s Genetic Tree 45 in dry desert soil and the third species grows in a salt marsh. To see how quickly new plant species could But when Rieseberg looked at the genomes of his hybrid sunflowers, he was surprised to find that they were just cut-and-pasted versions evolve, Rieseberg forced the two ancient sunflow- of the ancient sunflower species’ genomes: ers to interbreed with each other, something large chunks had been plants but not other organisms can do. Among moved rather than many the hybrid progeny were sunflowers that were just new SNPs created. like the three recently evolved species! What that Rieseberg reasons means is that Rieseberg had stimulated evolution that plants stash away in his lab, similar to what actually happened in unused genetic material, nature some 60,000 to 200,000 years ago, when giving them a ready supply of the newer species first arose. ingredients they can use to adapt That Rieseberg could do this is pretty amaz- quickly to a new environment. It may be that ing, but the really interesting part is how it human genomes can recycle unused genetic happened. Scientists generally assume that, for a material to confront new challenges, as well. new species with very different characteristics to evolve, a lot of new mutations have to occur. Plants like these sunflowers make great models for studying how evolution works. ALISON DAVIS 46 National Institute of General Medical Sciences 1 2 Living Laboratories Like most people, you probably think of fruit flies REX L. CHISHOLM Below is a sampling of the wide variety of as kitchen nuisances. But did you know that sci- living laboratories that scientists are using to entists use these organisms for medical research? advance human health. Fruit flies and other model organisms—as different as mice, plants and zebrafish—permit scientists to investigate questions that would not be possible to study in any other way. These living systems are, relatively speaking, simple, inexpensive and easy to work with. Model organisms are indispensable to science because creatures that appear very different from us and from each other actually have a lot in common when it comes to body chemistry. Even organisms that don’t have a body—mold and yeast, for example—can give scientists clues to the workings of the tissues and organs of people. This is because all living things process the nutrients they consume into the same chemicals, more or less. The genes for the enzymes involved in metabolism are similar in all organisms. 1 Escherichia coli: Bacterium “Once we understand the biology of Escherichia coli, we will understand the biology of an ele- phant.” So said Jacques Monod, a French scientist who won the 1965 Nobel Prize in physiology or medicine for his work on gene regulation. Monod was an early proponent of the value of experimenting with simple organisms like bacteria. Are all bacteria bad? If all you’ve ever heard about E. coli is its notorious link to tainted hamburger meat, you may not realize that non-disease-causing strains of the bacterium live in the intestinal tracts of humans and other animals, helping them in a variety of ways. For one thing, these bacteria are a main source of vitamin K and B-complex vitamins. They also aid digestion and protect against infection by harmful bacteria. The New Genetics I Life’s Genetic Tree 47 3 NAMBOORI B. RAJU Scientists all over the world have banded Dicty normally grows as separate, independent together to sequence different versions of the cells. However, when food is limited, neighboring E. coli genome. Among other things, these studies cells pile on top of each other to create a large, will help distinguish the genetic differences multicelled structure containing up to 100,000 between bacteria in a healthy human gut and cells. This blob ambles along like a slug, leaving those that cause food poisoning. a trail of slime behind. After migrating to a more suitable environment, the blob firms up into a 2 Dictyostelium discoideum: Amoeba This microscopic amoeba—100,000 of them form a mound as big as a grain of sand—is an important tool for health studies. Scientists have determined that Dictyostelium discoideum (Dicty) has somewhere between 8,000 and 10,000 genes, towerlike structure that disperses spores, each capable of generating a new amoeba. Because of its unusual properties and ability to live alone or in a group, Dicty intrigues researchers who study cell division, movement and various aspects of organ and tissue development. many of which are close copies of those in people and animals but are missing in another single- 3 Neurospora crassa: Bread Mold celled organism, yeast. Dicty was first discovered Chances are you don’t think of a moldy bread in the 1930s in a North Carolina forest and has crust as a potential science experiment, but since been found in many similar habitats around thousands of researchers around the world do! the world. Neurospora crassa (Neurospora), which is a species of mold that thrives on bread, is a widely used model organism for genetic research. 48 National Institute of General Medical Sciences 4 GARY DITTA 5 ALAN WHEALS Biologists like to use Neurospora because like yeast because it grows fast, is cheap to feed it is simple to grow and has features that make and safe to handle, and its genes are easy to work it very suitable for answering questions about with. We know a lot about mammalian genes how species arise and adapt, as well as how cells because scientists can easily insert them into yeast and tissues change their shape in different and then study how they work and what happens environments. Since Neurospora produces spores when they don’t work. on a 24-hour cycle, the organism is also useful for studying the biological clocks that govern sleep, wakefulness and other rhythms of life. 5 Arabidopsis thaliana: Mustard Plant Researchers who study plant growth often use Arabidopsis thaliana (Arabidopsis), a small, 4 Saccharomyces cerevisiae: Yeast flowering plant related to cabbage and mustard. There are hundreds of different kinds of yeast, but This organism is appealing to biologists because Saccharomyces cerevisiae, the one scientists study Arabidopsis has almost all of the same genes as most often, is an important part of human life other flowering plants and has relatively little outside the lab, too. It is the yeast that bakers use DNA that does not encode proteins, simplifying to make bread and brewers use for beer. the study of its genes. Like people and yeast, Like Neurospora, yeast is actually a fungus— plants are also eukaryotes. Arabidopsis grows not a plant, not an animal, but related to both. quickly, going from seed to mature plant in only It is also a eukaryote (as is Neurospora)—a 6 weeks—another plus for researchers who study “higher” organism with an organized, protective how genes affect biology. nucleus that holds its chromosomes. Researchers The New Genetics I Life’s Genetic Tree 49 6 7 What do you have in common with a mustard has a lot of genes—more than 19,000 (humans plant? Plant cells, and parts of plant cells, com- have about 20,000). Decoding the C. elegans municate with each other in much the same way genome was a huge milestone for biology, since that human cells do. For that reason, plants are it was the first animal genome to be sequenced good models for genetic diseases that affect completely. Scientists quickly learned that a vast cell communication. number of genes in C. elegans are very similar to genes in other organisms, including people. 6 Caenorhabditis elegans: Roundworm Caenorhabditis elegans (C. elegans) is a creature 7 Drosophila melanogaster: Fruit Fly that is a lot smaller than its name! Several of The fruit fly species most commonly used for these harmless roundworms would fit on the research is named Drosophila melanogaster head of a pin, although their usual habitat is (Drosophila). A geneticist’s fruit fly is pretty dirt. In the lab, they live in petri dishes and eat much the same as the ones that fly around your bacteria. C. elegans contains just 959 cells, overripe bananas. In the lab, though, some of almost a third of them forming its nervous the flies are exposed to damaging chemicals or system. Researchers know the fate of every one radiation, which changes the sequence of their of these cells! DNA. Researchers allow the flies to mate, then This worm is particularly prized by biologists search among the offspring for flies with because it is transparent, so what goes on in its abnormalities. The mutant flies are then mated tiny body is in plain view under a microscope. to produce more offspring with the abnormality, But for such a small, simple animal, C. elegans enabling researchers to close in on the defective genes involved. 50 National Institute of General Medical Sciences 9 MONTE WESTERFIELD 8 Fruit flies have been a favorite experimental Many researchers are drawn to zebrafish organism among geneticists since early in the because their eggs and embryos are transparent, 20th century. Hundreds of them can live in a making it possible to watch development unfold. pint-sized milk bottle or even a small vial, and In a span of 2 to 4 days, zebrafish cells split and they reproduce so quickly that keeping track form different parts of the baby fish’s body: eyes, of a particular gene as it passes through a couple heart, liver, stomach and so on. Sometimes, of Drosophila generations takes only about a researchers will move a cell to another spot to see month. It’s also relatively easy to create flies with if it will still go on to form the same part of the mutations in many genes, enabling scientists to body or if it will do something different. This study how the genes work together. research has taught scientists about a range of health-related matters in people, including birth 8 Danio rerio: Zebrafish Zebrafish were originally found in slow streams, defects and the proper development of blood, the heart and the inner ear. rice paddies and the Ganges River in East India and Burma. They can also be found in most pet 9 Mus musculus: Mouse stores and are a home aquarium favorite. The branches of life’s genetic tree that led eventu- Although the fish have been used by some ally to mice and to human beings split off from geneticists for research since the early 1970s, in each other 75 million years ago, back in the recent years they have become an especially dinosaur age. But we are both mammals, and we popular model organism. share 85 percent of our genes. Because some mouse diseases are very similar—sometimes The New Genetics I Life’s Genetic Tree 51 10 identical—to human diseases, mice are exceptionally valuable for research. Since the late 1980s, researchers have been Although rats are mammals just like mice, they differ in important ways. Rats are much bigger than mice, making it easier for scientists able to engineer mice with missing genes. to do experiments that involve the brain. For Scientists make these “knockout” mice to learn example, rats have taught scientists a lot about what goes wrong when a particular gene is substance abuse and addiction, learning, memory removed. This gives them valuable clues about and certain neurological diseases. Rats are also the gene’s normal function. Identifying these much better models than mice for studying genes in humans has helped define the molecular asthma and lung injury. And since, in people, the basis for many illnesses. disease arthritis is more common in women, studying rats makes more sense because female 10 Rattus norvegicus: Rat The Norway rat, or lab rat, was the first animal rats appear to be more susceptible to arthritis than male rats. The opposite is true with mice. domesticated for use in scientific research. Currently, they make up about one-fourth of all research animals in the United States. Lab rats have been used for many decades for testing drugs, and much of what we know about cancer-causing molecules was learned in basic research with rats. This Living Laboratories section is available as a poster. To order a free copy, visit http://publications.nigms.nih.gov/order. 52 National Institute of General Medical Sciences The Genome Zoo longer ago than the ancestor of humans and Scientists often use an image of a tree to depict chimpanzees, yet we still share hundreds of genes how all organisms, living and extinct, are related with bacteria. to a common ancestor. In this “tree of life,” each Scientists use the term comparative genomics branch represents a species, and the forks between to describe what they’re doing when they com- branches show when the species represented by pare the genomes of different species to see how those branches became different from one another. similar (or how different!) the species’ DNA For example, researchers estimate that the com- sequences are. Sequences that the species have in mon ancestor of humans and chimpanzees lived common are the molecular footprints of an about 6 million years ago. ancestor of those species. While it is obvious just by looking that people Why are “old” DNA sequences still in our have a lot in common with our closest living rela- genomes? It turns out that nature is quite eco- tives, chimpanzees, what about more distant nomical, so DNA sequences that are responsible species? If you look at an evolutionary tree, you’ll for something as complicated and important as see that humans are related to mice, worms and controlling gene activity may stay intact for even bacteria. The ancestral species that gave rise millions of years. to both humans and bacteria was alive a lot Comparative genomic studies also have medical implications. What would you do if you wanted to develop new methods of preventing, diagnosing or treating a human disease that animals don’t get? PHILLIP NEWMARK Starting All Over Again Stem cells —what embryos are made up of just days after an egg is fertilized by a sperm—have the amazing ability to develop into any kind of cell in the body, from skin to heart, muscle and nerve. Intrigued by the potential of these masterful cells, researchers want to know what gives stem cells their ability to change into a specific cell type upon the body’s request, but stay in the “I can do anything” state until asked. Some researchers are trying to figure out how stem cells work by using a unique model system: tiny, freshwater worms called planarians. These worms are like stem cells in the sense that they can regenerate. You can cut a planarian into hundreds of pieces, and each piece will grow into a complete worm. Planarians’ resemblance to stem cells isn’t just coincidental. Scientists have discovered The New Genetics I Life’s Genetic Tree 53 If people have a gene that influences their risk cytochrome P450 family, abbreviated 3A4 and for a disease, and mice have the gene too, you 3A5, encode proteins that process more than half could study some aspect of the disease in mice, of all of the medicines that are sold today. even though they don’t ever have the symptoms Since the chemicals to which people are of the disease. You could even study the disease exposed vary so widely, a scientist might pre- in yeast, if it has the gene, as well. dict that there would be different variants of cytochrome P450 genes in different human Genes Meet Environment If toxins from the environment get into our bodies, they don’t always make us sick. That’s because liver enzymes come to our rescue to make the chemicals less harmful. The genes that encode those enzymes are under constant evolutionary pressure to adapt quickly to new toxins. For example, certain liver enzymes called cytochrome P450 proteins metabolize, or break down, hormones that our bodies make as well as many of the foreign substances that we encounter. These include harmful molecules like cancercausing agents as well as beneficial ones, like populations. Using comparative genomics, researchers such as Anna Di Rienzo of the University of Chicago have shown that this is indeed the case. Di Rienzo has found many sequence differences within these genes in people living throughout the world. It turns out that one variant of the gene that encodes the cytochrome P450 3A5 protein makes this enzyme very efficient at breaking down cortisol, a hormone that raises salt levels in the kidneys and helps the body retain water. Di Rienzo compared the DNA sequences of the 3A5 gene in DNA samples taken from more than 1,000 people medicines. In fact, just two genes within the that planarians can perform the amazing act of regeneration due to the presence of, yes, specialized stem cells in their bodies. Developmental biologist Alejandro Sánchez Alvarado of the University of Utah School of Medicine in Salt Lake City used the gene silencing technique RNAi (see page 28) to identify planarian genes essential for regeneration. He and his team hope to figure out how these genes allow the specialized stem cells to travel to a wounded site and “turn into” any of the 30 or so cell types needed to recreate a mature worm. Although humans are only distantly related to planarians, we have many of the same genes, so these findings could reveal strategies for regenerating injured body parts in people, too. Scientists have also learned how to genetically reprogram human skin cells (and other easily obtained cells) to mimic the stem cells of embryos. In theory, these so-called induced pluripotent stem cells could generate any type of cell and be used to treat diseases. But to realize this potential, we need a much better understanding of the properties of these cells and how to efficiently produce cells that are safe for therapeutic uses. 54 National Institute of General Medical Sciences advantage for people living in a very hot climate, since retaining salt helps ward off dehydration caused by intense heat. However, there seems to be a cost associated with that benefit—the 3A5 gene variant raises the risk for some types of high blood pressure. That means that in environments in which retaining salt is not beneficial, evolution selects against this gene variant. Another scientist who studies interactions between genes and the environment is Serrine Lau of the University of Arizona in Tucson. She studies a class of harmful molecules called polyphenols, present in cigarette smoke and car exhaust, that cause kidney cancer in rats, and perhaps, in people. Lau discovered that rats and humans who are more sensitive to some of the breakdown products of polyphenols have an unusual DNA Scientists have discovered that some African populations near the equator have a high frequency of a genetic variant that helps the body conserve water. sequence — a genetic signature—that increases their risk of developing cancer. She suspects that the gene that is affected encodes a tumor suppressor: a protein that prevents cancer from representing over 50 populations worldwide. She developing. In people and rats with the genetic was amazed to find a striking link between the signature, she reasons, the tumor suppressor existence of the gene variant and the geographic doesn’t work right, so tumors grow. locale of the people who have it. Di Rienzo discovered that African populations Taking this logic one step further, it may be that certain people’s genetic make-up makes living very close to the equator were more likely them unusually susceptible to DNA damage than other populations to have the salt-saving caused by exposure to carcinogens. If doctors version of the 3A5 gene. She suggests that this is could identify those at risk, Lau says, such people because this gene variant provides a health could be forewarned to avoid contact with specific chemicals to protect their health. The New Genetics I Life’s Genetic Tree 55 However, think about this scenario: Who should make those decisions? For example, would it be ethical for an employer to refuse to hire somebody because the person has a genetic The liver and kidneys are signature that makes him or her more likely to susceptible to damage from toxins since these body organs process chemicals. get cancer if exposed to a chemical used in the workplace? Tough question. Liver Kidneys 56 National Institute of General Medical Sciences GENETICS AND YOU: W You’ve Got Rhythm! hat do waking, sleeping, The human body keeps time with eating, reproducing and a master clock called the suprachiasmatic birds flying south for the nucleus or SCN. Situated inside the brain, winter have in common? These are all it’s a tiny sliver of tissue about the size of a examples of nature’s amazing sense of grain of rice, located behind the eyes. It sits rhythm. All living things are equipped quite close to the optic nerve, which con- with molecular timepieces that set the trols vision, and this means that the SCN pulse of life. “clock” can keep track of day and night. If you’ve ever crossed the country or Given enough time, your SCN can reset an ocean by plane, you know about the itself after you fly in an airplane from one importance of these clocks. You proba- time zone to another. bly experienced that traveler’s misery The SCN helps control sleep by coordi- called jet lag, where the body is forced nating the actions of billions of miniature to adapt quickly to a new time zone. “clocks” throughout the body. These aren’t But did you know that certain forms actually clocks, but rather are ensembles of of insomnia and manic-depressive illness genes inside clusters of cells that switch on are associated with biological clocks and off in a regular, 24-hour cycle—our not working properly? And biological physiological day. rhythms may be the reason why some Scientists call this 24-hour oscillation medicines and surgical treatments a circadian rhythm. (“Circadian” comes from appear to work best at certain times the Latin words meaning “approximately of day. a day.”) Researchers have discovered that all living things—plants, animals and bac- Light Output rhythms: physiology behavior teria— have circadian rhythms. Many researchers working with insect and other model systems have identified genes that are critical for keeping biological time. Understanding circadian rhythms will help scientists better understand sleep disorders. If we have the opportunity, most of us sleep 7 or 8 hours at night, and if we don’t get Suprachiasmatic nucleus (SCN) enough rest we may have a hard time getting things done the next day. Some people, The New Genetics I Life’s Genetic Tree 57 however, routinely get by with only 3 to Although the shaker flies don’t 4 hours of sleep. Researchers have noted appear sleep-deprived, Cirelli found that that this trait seems to run in families, they have a different problem: They suggesting a genetic link. don’t live as long as flies without the As it turns out, fruit flies need even mutation. She is now studying this new more sleep than people. Neuroscientist connection between sleep and lifespan. Chiara Cirelli of the University of Her work may also pave the way for Wisconsin-Madison did a genetic search improved sleep aids and effective for fruit fly mutants that don’t sleep remedies for jet lag. much. She discovered that flies with a variant of a gene called shaker sleep only 3 to 4 hours per night. 58 National Institute of General Medical Sciences Animals Helping People melanogaster, a fruit fly species widely used Using technology that grew out of the Human in genetic research (see Living Laboratories, Genome Project, scientists have read the page 49). sequences of the genomes of hundreds of organ- Currently, Bier and other scientists are using isms: dogs, mice, rats, chickens, honeybees, fruit experimental flies to investigate a wide range of flies, sea urchins, pufferfish, sea squirts, round- genes involved in conditions such as blindness, worms and many bacteria and fungi. Next in deafness, mental retardation, heart disease and line are dozens of additional species, including the way in which bacterial toxins cause illness. a marmoset, a sea skate, an alpaca, an anteater and many reptiles. What effect will all this gene sequence information have on medical research? We’ve already talked about the fact that people share many of By reading the DNA sequences of many other species, researchers hope to find model systems that are even better than fruit flies for studying some aspects of human disease. Sometimes, the genes that we don’t have in their genes with other species. This means that common with other species are as important as when scientists read the sequence of another the genes we share. For example, consider the fact species’ genome, they’re likely to discover that the that humans and chimpanzees have remarkably organism has many of the genes that, in humans, different abilities and physical features. But the cause disease or raise disease risk when mutated. chimpanzee genome is 99 percent identical to Take fruit flies as one example. According to biologist Ethan Bier of the University of California, San Diego, 30 percent of the currently identified human disease genes most likely have functional counterparts in none other than Drosophila our own. And did you know that chimpanzees don’t get malaria or AIDS? So a tiny portion of our genome determines whether we look and behave like a person or a chimp, and whether we are susceptible to malaria or AIDS. My Collaborator Is a Computer We’ve made the case that comparing genomes can offer fresh insight on the basic genetic ingredients for health and the causes of disease. But what does a scientist actually do when he or she compares gene sequences? Does this mean staring at thousands of pages of genetic letters, looking for those that are the same or different? The New Genetics I Life’s Genetic Tree 59 Computers are an essential tool for scientists who store and analyze huge amounts of genomic data. Read more about computers and biology at http://publications. nigms.nih.gov/ computinglife. Yes and no. Comparative genomics does things, the programs can figure out where in involve looking for similarities and differences, the DNA sequences a gene starts and stops: but it isn’t something that scientists do by hand. its “boundaries.” Certainly not for thousands of genes at a time. Rather, the gigantic task of comparing the Other researchers who work in the field of bioinformatics mine genomic information hid- nucleotides that make up the genomes of two or den in the masses of data. They are looking for more species is the perfect job for a computer, a scientific treasure in the form of new biological natural multitasker. If you consider that the knowledge. These experiments can zero in on pre- human genome contains 3 billion nucleotides, viously hidden patterns and reveal links between you can easily see why this is work well suited to different fields of research. a machine (with a human operator, of course). Researchers called computational biologists Bioinformaticists and computational biologists are in high demand because they play a very help analyze genomic data. These scientists important role in 21st-century medical science. develop software programs that enable computers These scientists must be fluent in both computer to perform genome comparisons. Among other science and biology. 60 National Institute of General Medical Sciences The Tools of Genetics: Unlimited DNA You might be amazed to learn that a microbe that essential to a laboratory technique called the lives in a boiling hot spring in Yellowstone polymerase chain reaction, or PCR. And PCR National Park is the essential ingredient for one is essential to lots of things that life scientists of the most important biological research tools do—and to many other fields, too. PCR’s inven- ever invented. tor, Kary Mullis, won the 1993 Nobel Prize in Thermus aquaticus is a bacterium that makes a heat-resistant enzyme, which is why it can thrive in hot springs. The enzyme, Taq polymerase, is chemistry. PCR is a quick, easy method for generating unlimited copies of tiny amounts of DNA. Words A microbe that lives in hot springs, like this one in Yellowstone National Park, is home to the enzyme that makes the polymerase chain reaction, or PCR, possible. PCR machine. APPLIED BIOSYSTEMS Got It? Discuss reasons why research like “revolutionary” and “breakthrough” are not an exaggeration of its impact. PCR is at the heart of modern DNA PCR is a key element of “genetic fingerprinting,” which has helped free prisoners who relied on it to prove got them locked up. Conversely, it has pro- pinpointing mutations in genes, so it is the vided scientific evidence that helped convict basis for much of the research discussed in criminals. PCR has even revolutionized archaeology what the invention of the printing press did by helping to analyze badly damaged ancient for written material. It makes copying easy, DNA—sometimes thousands of years inexpensive and widely available. old—which can reveal new information PCR underlies many diagnostic techniques, like testing individuals for genes that cause can provide valuable information about health and disease. that they were innocent of the crimes that sequencing methods. It is essential for this booklet. PCR has done for genetic material studies with identical twins about past people and cultures. Humans and mice share over 80 percent of the same genetic material: for chimps and humans, it’s more than 99 percent. Why are people and animals so different, if their genes are so similar? Scientists predict that future uses of PCR breast cancer. It can also help diagnose diseases technology will enhance medical treatment, other than cancer, such as infections by HIV enabling better diagnosis and more accurate and hepatitis C. subtyping of disease. You are a scientist and you want to learn more about how humans age. Is there a way you can address your research question without spending many decades studying people? Can you think of an experiment using fruit flies that could help researchers better understand jet lag? CHAPTER 4 Genes Are Us F or science, the sequencing of the human changes create words with new meanings— genome was a groundbreaking achievement, genes that code for different proteins. Other one that made a lot of news. But what does it spelling changes appear to have no effect actually mean? Will any of this information make whatsoever, at least not ones that today’s scien- a difference in your life? tists know how to measure. A genome is all of the genetic material that an Researchers are beginning to use knowledge individual (or a species) has. The human genome learned from genome sequencing research to differs from the gorilla genome, which differs figure out how being healthy and being sick are from the rice genome, and so on. And while every different at the level of molecules. And doctors person has a “human genome,” it is not exactly are starting to use genetic information to make the same in all people. Sequence variations treatment choices. within your genes makes your DNA different For example, a diagnostic test can search for from that of your mother, your cousin or a differences in the level of expression of a particu- complete stranger. lar gene in breast cancer cells and predict whether Think of the human genome as a long story a person will respond to a drug called Herceptin®. that contains roughly 20,000 words (the genes). The cancerous cells of some people who have With few exceptions, each person has the same breast cancer make an abundance of “HER2” number of words, but certain words have slightly proteins that are targeted by Herceptin. For those different spellings. In some cases, the spelling people, Herceptin is a miracle drug because it L. BARRY HETHERINGTON Reading the Book of Human Genes Many DNA sequencing centers joined efforts to form the Human Genome Project, completed in 2003. Now the centers, like this one at the Broad Institute of MIT and Harvard University in Cambridge, Massachusetts, are working to better understand the human genome and to sequence the genomes of other organisms. In April 2003, researchers across the world celebrated a milestone and an anniversary. Almost 50 years to the day after James Watson, Francis Crick and Maurice Wilkins unveiled their Nobel Prizewinning description of the DNA double helix, scientists completed the sequencing of the human genome, a momentous achievement in biology. The day was long in coming. In the 1980s, geneticists realized that they had both the need and the ability to learn the complete layout of the human genome. They wanted to map the location of every gene within chromosomes and decipher the complete, letter-by-letter sequence of the genome’s 3 billion nucleotides. The New Genetics I Genes Are Us 63 reduces the risk that their breast cancer will come though, so it shouldn’t be prescribed. Research is back, and it also decreases their odds of dying proceeding quickly to develop other genetic tests from the disease. that may help diagnose and treat a wide range of For cancer patients whose tumor genes do health problems beyond cancer. not express HER2, Herceptin won’t do a thing, With that information in hand, scientists reasoned, it would eventually be possible to learn exactly what job each gene performs as well as how genes contribute to human health and disease. Soon, thousands of scientists in labs all over the world got into the act. Critical to their success were new tools and technologies that made the work go faster and helped the researchers manage and analyze the flood of data. Although the Human Genome Project is done, related genome sequencing efforts have continued. One involves sequencing the genomes of many other species (see page 58). Another is roughly sequencing the genomes of 2,000 people to produce a detailed haplotype map showing both common and rare patterns of genetic variation. Researchers can link these variations to disease risk and health-related traits, such as individual reactions to medicines and environmental chemicals. 64 National Institute of General Medical Sciences Individualized Prescriptions Because each person’s set of genes is a little One way variations in our genes make a differ- different, the proteins that the genes encode are ence in our health is by affecting how our bodies also slightly different. These changes can affect react to medicines. The unsettling truth is that how the cytochrome P450 proteins (and many medicines work as expected in fewer than half of other types of proteins) work on drugs. the people who take them. While environmental and lifestyle factors Doctors first realized this in the 1950s, when some patients had bad—sometimes fatal— can explain some of this, a good part of the reactions to an anesthetic medicine used in surgery. individual variability in response to medicines Experiments revealed that those who reacted can be attributed to variants in the genes that poorly had a genetic variation in the enzyme that make cytochrome P450 proteins (see page 53). breaks down and disposes of the anesthetic after These proteins process many of the drugs it’s been in the body for a while. we take. People whose genes encode the variant enzyme had no trouble at all until they needed surgery that required general anesthesia. In the operating room, a normal human genetic variation suddenly led to a medical crisis! Fortunately, this type of serious reaction to an anesthetic is very rare. But many reactions to medicines aren’t so unusual. Researchers know that genetic variations can cause some common medicines to have dangerous side effects. For example, some people who take the colon cancer drug Camptosar® (also known as irinotecan) can develop diarrhea and a life-threatening infection if they have a variant form of the gene for the protein that metabolizes Camptosar. Genetic variations can also cause drugs to have little effect at all. For example, in some people, Did you know that medicines work like they’re supposed to in fewer than half of the people who take them? Genetic differences among people are one reason. pain medicines containing codeine, like Tylenol® with Codeine Elixir, offer no relief because their bodies break it down in an unusual way. The New Genetics I Genes Are Us 65 The use of genetic information to predict how people will respond to medicines is called pharmacogenetics. The ultimate goal of this field of study is to customize treatments based on an individual’s genes. With this kind of approach, every patient won’t be treated the same, because doctors will have the molecular tools to know ahead of time which drug, and how much of it, to prescribe— or whether to prescribe it at all. The Healing Power of DNA Pharmacogenetics is advancing quickly since scientists have a lot of new information from the Pharmacogenetic researchers have discovered that a gene test can predict which children with acute lymphoblastic leukemia will be cured by chemotherapy. Human Genome Project and new computer tools that help them analyze the information. One disease for which progress has been rapid is cancer. Consider the fact that cancer is often treated with a chemotherapy “cocktail,” a combination common childhood cancer. The remaining 20 of several different medicines. Each of the drugs percent are at risk of the cancer coming back. in the mixture interacts with different proteins Mary Relling, a research clinical pharmacist that control how well that particular drug works at St. Jude Children’s Research Hospital in and how quickly it is metabolized in the body. Memphis, Tennessee, discovered that variations What’s more, each drug may have its own set of in two genes can predict which patients with unpleasant—even potentially life-threatening— acute lymphoblastic leukemia are likely to be side effects. cured by chemotherapy. Her research team also For these reasons, individually targeted, gene- identified more than 100 genes expressed only in based prescriptions for chemotherapy may offer cancer cells that can be used to predict resistance a real benefit to people with cancer. to chemotherapy drugs. Currently, chemotherapy cures about 80 per- By taking patient and cancer cell genetic pro- cent of the children who have been diagnosed files into account, Relling says, researchers can with acute lymphoblastic leukemia, the most develop more effective treatments for the disease. 66 National Institute of General Medical Sciences Genetic variation produces different individual responses to the blood-thinning drug Coumadin®. A genetic test could lead to more accurate doses. Other pharmacogenetic scientists are studying the effects of gene variants on patients’ responses to drugs used to treat AIDS, allergies, infections, asthma, heart disorders and many other conditions. For example, researchers recently identified who are taking the same dose. Giving the right dose is essential, because too much Coumadin can cause excessive bleeding, while too little can allow blood clots to form. Allan Rettie, a medicinal chemist at the University of Washington in Seattle, discovered that genetic variation among people influences two different genetic variants that play a central the activity of a protein in the blood that is role in determining the body’s response to Coumadin’s molecular target. He and other sci- Coumadin® (also known as warfarin), a widely entists are now trying to translate these findings prescribed medicine given to people who are at into a genetic test that could help doctors predict risk for blood clots or heart attacks. Although what dose of Coumadin is appropriate based on 2 million Americans take this blood-thinning each patient’s DNA profile. drug every day, it is very difficult to administer, since its effects vary widely in different people ZACHARY HUANG, HTTP://CYBERBEE.MSU.EDU Genes Can Do That? Honeybees are social animals and they work together to keep their hive healthy. The forager bee (on the left) is about a month old and hunts for food. The 14-day-old undertaker bee (on the right) removes dead bees from the hive. Did you know that, in addition to traits you can see like hair color and physique, genes also contribute to how we behave? It may come as a surprise that many researchers are answering basic questions about the genetics of behavior by studying insects. For example, Gene Robinson, an entomologist at the University of Illinois at Urbana-Champaign, works with honeybees. Robinson says that if you look at honeybees in their natural hive environment, you’ll quickly see that they are very outgoing. In fact, according to Robinson, honeybees can’t survive without the social structure of their community within the hive. This characteristic makes them a perfect species in which to study the genetics of behavior. What’s particularly interesting about bees is that rather than being stuck in a particular job, they change jobs according to the hive’s needs. Robinson has identified certain genes whose activity changes during a job shift, suggesting that the insects’ environment helps to shape their gene expression. Researchers who are beginning to understand these connections are working in a brand-new field of investigation named by Robinson himself: sociogenomics. What does all of this mean for humans, you wonder? It underscores the fact that, far from being set in stone, our genomes are influenced by both heredity and environment, fine-tuned and sculpted by our social life and the things we do every day. The New Genetics I Genes Are Us 67 Cause and Effect What more do we need to know about how genes shape who we are and what we become? “A lot,” says Harvard’s Richard Lewontin, who warned against oversimplifying the role of genes in health in his 2001 book, The Triple Helix. Lewontin’s main point is that context plays an enormous role in determining how organisms grow and develop, and what diseases they get. A unique combination of genetic and environmen- disease, diabetes or particular types of cancer tal factors, which interact in a way that is very hard “run in your family,” especially if a lot of your to predict, determines what each person is like. relatives get the condition when they are fairly Very few, if any, scientists would argue with this. Whether a gene is expressed, and even whether the mRNA transcript gets translated young, you may want to talk with your doctor about your own risk for developing the disease. In 2005, the U.S. Surgeon General developed into a protein, depends on the environment. a Web-based tool for organizing family health Few diseases—most of which are very rare— information. Called “My Family Health Portrait” are caused completely by a mutated gene. (see http://www.hhs.gov/familyhistory), this tool In most cases, getting or avoiding a disease arranges information into a printout that you can depends not just on genes but on things within carry to the doctor’s office. The information can your control, such as diet, exercise and whether help you and your doctor determine your risks or not you smoke. for various conditions. It will be many years before scientists clearly If you do discover that you are at higher-than- understand the detailed meaning of our DNA usual risk for a disease like breast cancer or heart language and how it interacts with the environ- disease, you may be able to prevent the disease, or ment in which we live. Still, it’s a great idea to delay its onset, by altering your diet, exercising find out as much as you can about your family’s more or making other lifestyle changes. You may health history. Did any of your relatives have also be able to take advantage of screening tests diabetes? Do people in your family tree have like mammograms (breast X rays that detect signs cancer or heart disease? of cancer) colonoscopies (imaging tests for colon Keep in mind that diseases such as these are cancer) or blood sugar tests for diabetes. relatively common, so it’s pretty likely that at least Screening tests can catch diseases early, when one relative will have one of them. But if heart treatment is most successful. Knowing about diseases that run in your family can help you guard against illness in the future. 68 National Institute of General Medical Sciences Resistance to antimalarial drugs like chloroquine is widespread throughout much of Africa and other parts of the developing world where malaria transmission is high. Countries with malaria that is resistant to chloroquine CENTERS FOR DISEASE CONTROL Countries with malaria that is sensitive to chloroquine AND PREVENTION Us vs. Them So why don’t they kill human cells, too? The Many scientists focus on human genes, most of answer is that human and bacterial ribosomes are which have counterparts in the genomes of different. Genome sequencing is a powerful tool model organisms. However, in the case of infec- for identifying differences that might be promis- tions caused by microorganisms, understanding ing targets for new drugs. how the genomes of bacteria, viruses and para- Comparing genetic sequences in organisms sites differ from ours is a very important area of that are resistant and non-resistant to drugs can health research. reveal new approaches to fighting resistance. Most of the medicines we take to treat infections by bacteria and viruses have come from scientists’ search for molecular weak points in Drug resistance is a worldwide problem for a number of diseases, including malaria. Although researchers have developed several these tiny organisms. As mentioned in Chapter 1, different types of medicines to treat this dis- for example, some antibiotics kill bacteria by ease—caused by parasites carried by mosquitoes, disarming their protein-making ribosomes. not by a bacterium or a virus—malaria is rampant, especially in the developing world. The New Genetics I Genes Are Us 69 GENETICS AND YOU: W Eat Less, Live Longer? ould you consume an ex- that by restricting the tremely low-calorie diet if it formation of extra DNA, meant you would live longer? The kind of diet we’re talking about isn’t just cutting back here and there. It sirtuins keep the yeast young. Not so fast, say other involves severely reducing calorie intake scientists like geneticist to about 60 percent of what we nor- Stanley Fields of the mally eat, enough to make most people University of Washington. His experiments ravenously hungry. have turned up other, unrelated genes A 19th-century French doctor, linked to lifespan in yeast. He argues that Maurice Gueniot, thought the tradeoff while calorie restriction is the only inter- would be worth it. Throughout his adult vention that has been shown to extend life, he ate very little. He died at the ripe lifespan in a wide range of organisms, old age of 102! including mammals, the accumulation of Later, in the 1930s, researchers followed up on this observation by showing that rats on a diet containing 20 percent indigestible fiber—calories that can’t be used—lived much longer than their normally fed peers. extra DNA does not always appear to play a role in this process. What’s the final answer, you ask? It’s probably a bit of both. Molecules like sirtuins, which are involved in cellular metabolism, may pro- Intrigued by the health connection, tect cells against the harmful effects of scientists are continuing to investigate stress, extending lifespan. Other mole- potential links between diet and aging, cules that affect different aspects of cell and genetic studies are starting to turn health may be just as important. up some clues. For example, geneticist David Sinclair Lifespan in complex, multicellular organisms like people is affected by many of Harvard Medical School has found that different factors, most of which we know proteins known as sirtuins may be able to very little about. For sure, understanding stall aging. As yeast cells age, they accu- more about these mystery molecules mulate extra DNA, which eventually kills could have a considerable benefit— them. Sinclair discovered that sirtuins perhaps providing you a chance to add become more active in yeast cells that years to your life without starving! are on a low-nutrient “diet.” He reasons 70 National Institute of General Medical Sciences CDC/ JAMES GATHANY This is partly because not all people Did you know that scientists are using genetics to have access to treat- break up gangs … of microbes, that is? These ment, or to simple gangs, known as biofilms, are layers of slime that preventive measures like develop naturally when bacteria congregate on bed nets, which protect surfaces like stone, metal and wood. Or on your sleeping people from teeth: yuck! mosquito bites. But another problem is the Mosquitoes spread malaria by picking up parasites from blood and spreading them to the next person they bite. Resistance spreads this way, too. Gang Warfare Biofilms grow in all sorts of conditions. For example, one biofilm known as “desert varnish” malaria parasite itself, which has rapidly evolved thrives on rocks, canyon walls or, sometimes, ways to avoid the effects of antimalarial drugs. entire mountain ranges, leaving a reddish or Scientists are trying to counter this process by other-colored stain. It is thought that petroglyphs studying microbial genetic information. In the left on boulders and cave walls by early desert case of malaria, geneticists like Dyann Wirth of dwellers were often formed by scraping through the Harvard School of Public Health compare the the coating of desert varnish formations with a genomes of drug-resistant parasites and those hard object. that can still be killed by antimalarial medicines. Wirth’s research suggests that it should be Sometimes, biofilms perform helpful functions. One of the best examples of the use of possible to develop a simple, inexpensive genetic biofilms to solve an important problem is in the test that could be given to people with malaria, cleaning of wastewater. anywhere in the world. This test would identify drugs that are likely to be most effective and help decrease the rate at which parasites become resistant to the antimalarial medicines we already have. fluorescent microscopic photo, are bacterial communities. P. SINGH AND E. PETER GREENBERG Biofilms, like the one shown in this The New Genetics I Genes Are Us 71 Bonnie Bassler (right) uses glow-in-the dark bacteria to study the genetics of biofilms. DENISE APPLEWHITE But biofilms can be quite harmful, contributing to a wide range of serious health problems including cholera, tuberculosis, cystic goal of being able to use this knowledge to break up bacterial “gang meetings.” Bassler’s research subjects have a definite fibrosis and food poisoning. They also underlie visual appeal. They glow in the dark, but only many conditions that are not life-threatening when they are part of a group. The biolumines- but are nonetheless troublesome, like tooth cence, as the glow is called, arises from chemical decay and ear infections. reactions taking place within the biofilm. It pro- Bacteria form biofilms as a survival measure. vides a way for the bacteria to talk to each other, By living in big groups rather than in isolation, estimate the population size of their community the organisms are able to share nutrients and and distinguish themselves from other types of conserve energy. How do they do it? microorganisms. A biofilm is not just a loose clump of cells— Through her studies, Bassler has identified a it’s a highly sophisticated structure. As in any set of molecules that biofilm-forming microor- community, the individuals in biofilms commu- ganisms use to pass messages to each other. By nicate with each other. devising genetically based methods to cut off Beyond that, many aspects of biofilms are the chatter, Bassler reasons, she may be able to poorly understood. Bacterial geneticist Bonnie cause bacterial communities to fall apart. This Bassler of Princeton University in New Jersey is approach would provide a whole new way to treat working to understand biofilms better, with the health problems linked to harmful biofilms. 72 National Institute of General Medical Sciences The Tools of Genetics: Mathematics and Medicine What if public health officials had a script for Since 2005, the Models of Infectious Disease what to do in the face of an infectious disease Agent Study (MIDAS), a team of biologists, com- outbreak that had never been seen before? One puter scientists, statisticians, mathematicians, thing that would help them prepare for this sort social scientists and others, has been modeling of scenario is the ability to know, ahead of time, a flu pandemic—a huge, global epidemic. how an epidemic develops and spreads. Toward this goal, some scientists are using Initially, the models focused on avian influenza, a type of disease occurring naturally mathematical tools to create simulations, or among wild birds. At the time, health experts models, of infectious disease outbreaks. They worldwide worried that the virus’ genetic mate- can then use the models to test the effects of rial could mutate, making it much easier for the various intervention strategies. Part of the work so-called “bird flu” to pass between humans. involves plugging in genetic information about To simulate the potential disease spread, the how infectious organisms evolve over time scientists wrote computer programs that incorpo- and how fast they change as they interact with rated information about the bird flu virus and human populations. actual communities. Including details about people—not just their ages and genders, but also where they live, work or go to school—let the researchers create a synthetic population that could mirror how a real one might get sick and spread disease. The scientists ran the programs on large computers to see how the flu could spread with and without different interventions. The results indicated that to successfully contain an epidemic, health officials would need to find the first flu cases fast and implement a combination of public health measures very quickly. Computer simulations are helping scientists understand how infectious diseases spread. Got It? Discuss how mathematics can help scientists ask questions about human health. Would you contribute a sample of your DNA for This early work helped MIDAS scientists During both the bird and swine flu model- develop similar models of H1N1 or “swine flu,” ing efforts, the MIDAS scientists worked the first actual pandemic flu strain since 1968. closely with public health officials to address Starting in April 2009, they gathered incoming specific questions. The answers informed U.S. public health data to simulate the potential pandemic flu preparedness planning. spread of this global flu, identify the groups most Influenza, however, is not the only infec- likely to get sick and evaluate the usefulness of tious disease making people sick. MIDAS different public health measures, such as vaccina- scientists are also modeling other major health tion and quarantine. Their models suggested that threats, including cholera, dengue fever, vaccinating schoolchildren early in an outbreak malaria, tuberculosis and methicillin-resistant could reduce overall disease spread and that Staphylococcus aureus (MRSA). people at risk of serious complications should be given antiviral medications to take at the first signs of illness. genetic research on common diseases like heart disease, depression or cancer— even if you didn’t have any of these health problems? Why or why not? Drugs work like they’re supposed to in only half the people who take them, so scientists are trying to make “personalized medicines” that work very well in an individual because they match his or her genetic make-up. Are there economic, social or other issues that the development of such medicines might raise? CHAPTER 5 21st-Century Genetics M century, anatomy was a common focus for scientific scholars. practices like opening the vein of a sick person the earliest human civilizations, when and draining off quarts of precious blood! the diagnosis and treatment of disease were far Later, in the Renaissance period of the 15th from scientific. Medieval medicine, for example, and 16th centuries, scholars centered on anatomy. relied heavily on supernatural beliefs. Limited One of them, the Italian artist-inventor Leonardo scientific knowledge led to seemingly bizarre da Vinci, created beautiful and accurate RARE BOOK AND SPECIAL COLLECTIONS DIVISION, LIBRARY OF CONGRESS By the end of the 16th edicine has evolved tremendously since The New Genetics I 21st-Century Genetics 75 19th-century scientists illustrations of the human body. His work discovered that bacteria can cause disease. Bacillus anthracis (left) causes anthrax and Vibrio cholerae (below) causes cholera. and that of other scientists of his day focused on the practice of dissection, providing never-before-seen details of PAUL KEIM (ANTHRAX), the body’s architecture of limbs, joints, CDC/ WILLIAM A. CLARK (CHOLERA) muscles, nerves and vessels. Modern medicine got its real start during the 19th century, after the microscope was invented. Medical school subjects like physiology, pathology and microbiology were born. During this time, scientists discovered that bacteria—not evil spirits or other imaginary One of today’s challenges is to map the entities—caused human diseases like cholera, actions and interactions of all these molecules, anthrax and tuberculosis. a focus of the new field called systems The birth of modern genetics, which biology. Genetic and genomic occurred in the 20th century, accelerated the research is helping scien- study of all these areas of science. Now, at tists tackle many the start of the 21st century, opportunities questions in this have never been greater for turning scientific area. By building knowledge into better health for all. models of cells, We often take for granted the amazing tissues and complexity of the human body. Without even organs in action, thinking, we sweat to maintain body tempera- scientists hope to ture, get hungry when we need energy and feel learn how these tired when we need to sleep. complex, dynamic These seemingly simple actions require a sophisticated coordination of many different systems work. Researchers need to know organs and the millions of molecules that work these basics in order to understand how the together inside them. Thousands of networks systems fail, when disease strikes. An essential of interacting genes underlie these actions in tool in this research is the computer. our bodies. But these systems are proving to have far more fluctuation than scientists originally suspected. 76 National Institute of General Medical Sciences No Lab? No Problem! Those who work at the intersection of computer science and biology often combine and analyze data from many different sources, looking for informative patterns. Andrey Rzhetsky of the University of Chicago is one of these people. Through an approach known as knowledge engineering, Rzhetsky and his team write computer programs that scan the contents The program first scans scientific papers of thousands of published scientific papers. using pre-set search terms, much like a Google™ The “knowledge mining” tool they use, called search of the Web. Next, it evaluates the search GeneWays, focuses mainly on research literature results and makes sure they don’t overlap. For about changes in genes and proteins. example, if a molecule has 16 different names in different papers, the program simplifies it to just one. CATHERINE FERNANDEZ AND JERRY COYNE Green Fluorescent Protein Fruit fly sperm cells glow bright green when they express the gene for green fluorescent protein. Here’s an interesting news flash: “Glow-in-the-dark jellyfish revolutionizes genetic research!” Although it may sound bizarre, the claim is true. A jellyfish protein is essential to modern cell biology experiments that track the movements, quantities and interactions of the millions of proteins inside cells. Called green fluorescent protein, or GFP, this natural protein is found in specific parts of the jellyfish. Those parts glow because the protein absorbs energy from light in the environment and then produces a different color of light. Scientists don’t really know how and why jellyfish use their glow. They do know that jellyfish don’t flash at each other in the dark, nor do they glow continuously. And the glow is rarely seen in undisturbed animals. Taken out of the jellyfish, GFP has played a major role in advancing the study of genes and the proteins they encode. The story of how GFP The New Genetics I 21st-Century Genetics 77 Finally, after applying specific rules, sort of like “biological grammar,” the computer program identifies associations, which are possible links between molecules. The information then goes to a database that Rzhetsky and other scientists use to build large networks of molecular interactions. Rzhetsky and his team used GeneWays to identify risk genes for Alzheimer’s disease, a complex condition thought to be caused by many factors. In analyzing the data, Rzhetsky found important “nodes,” molecules that play key roles in the disease gene network that GeneWays modeled. ANDREY RZHETSKY AND KEVIN P. WHITE These predicted molecular interactions were later confirmed by other researchers working in a lab, underscoring the value of computer modeling as a way to learn more about the molecular basis of disease. Andrey Rzhetsky uses the computer program GeneWays to locate important “hubs” of activity (large spheres) within massive gene networks. This particular network represents embryonic developmental pathways in a fruit fly. used the GFP gene to create green-glowing zebrafish. Although the fish were created for the purpose of scientific research, they’ve also become an “exotic” species for home aquariums. Thanks to GFP and related technologies, scientists can now view living cells and their constantly moving contents. GFP is also used in diagnostic tests for drugs, foods, herbicides and hazardous chemicals. Chalfie and two other scientists received the 2008 Nobel Prize in chemistry for the discovery and development of GFP. MARTIN CHALFIE became a research tool began in 1992, when Martin Chalfie of Columbia University showed that the gene that makes GFP produced a fluorescent protein when it was removed from the jellyfish genome and transferred to the cells of other organisms (see page 38). Chalfie, a developmental biologist, first put the gene into bacteria and roundworms, creating glowing versions of these animals. Since then, researchers have transferred the GFP gene into many other organisms, including fruit flies, mice and rabbits—and even human cells growing in a lab dish. Recently, scientists Scientists engineered this experimental worm to express green fluorescent protein in two of its nerve cells (bright green spots). 78 National Institute of General Medical Sciences Another law, the Genetic Information Nondiscrimination Act, or GINA, prohibits discrimination in health coverage and employment based on genetic information. It’s important to realize that, in most cases, genetic information cannot offer definitive proof that a disease will occur. But if you have a very strong family history of breast cancer, for example, there may be a faulty gene in your family that Hard Questions increases your risk of getting the disease. While the task of sorting through large volumes Doctors can now test for two known gene of genomic data remains a central challenge in variants associated with inherited forms of breast modern biology and medicine, one of the knotti- cancer, BRCA1 and BRCA2. If you carry either of est dilemmas to emerge from this research is a these gene variants, your lifetime risk of getting social and ethical one. That is, how should people breast cancer is significantly higher than it would make use of information about their own genes? be for someone without either variant. But some Because genetic information is both powerful and incredibly personal, there are deep societal concerns regarding its use. These concerns people who have BRCA gene variants never get breast cancer. Only about 5 percent of all breast cancer include the potential for discrimination on the can be traced to a known, inherited gene basis of a person’s risk of disease or susceptibility variant. Since so many breast cancers are not to toxicity from an environmental chemical. linked to BRCA1 or BRCA2, genetic testing for Some laws are already in place to protect these variants is irrelevant for the vast majority individuals from the misuse of their genetic of people who do not have a family history of information. When you visit a new doctor, nurse breast cancer. practitioner, or dentist, you’ll be asked to read But let’s say you do have a relative who tested and sign a form that outlines your medical positive for BRCA1 or 2. Should you get tested, too? privacy rights under the Health Insurance A difficult question, for sure, but consider Portability and Accountability Act, or HIPAA. this: Knowing about this risk ahead of time This law protects your genetic and other personal might save your life. For example, you might health information from being used or shared want to begin getting mammograms or other without your knowledge. screening tests at an early age. If cancer is found The New Genetics I 21st-Century Genetics 79 very early, it is usually more treatable, and the this gene can cause the disease, and those are odds for a cure are much higher. just the ones researchers know about! Currently, diagnostic laboratories across the How can there be 30 different variants of United States offer genetic tests for almost 2,000 one gene? Remember that a gene is a long disorders. Some of these tests detect problems DNA sequence, consisting of hundreds of with entire chromosomes, not just individual nucleotides. A change in one of those genes. Perhaps the most well-known example of nucleotides produces one variant, a change in a chromosome problem is Down syndrome, in another produces another variant, and so on. which cells have an extra copy of chromosome 21 (see page 11). Because there are so many possibilities, it’s hard to tell whether a person has a variant Most genetic diseases aren’t caused by a form of the cystic fibrosis gene. So the standard chromosome abnormality, or even by one gene genetic screening test for this disease scans for variant. Cystic fibrosis, for example, is due to a all of the more than 30 variants known to cause faulty gene, but more than 30 different variants of cystic fibrosis. Scientists are developing genetic tests that will help doctors diagnose and treat diseases. 80 National Institute of General Medical Sciences Doctors usually order a genetic test only if As a teen or young adult, would you want to a person has a strong family history of a disease. know that you’d get a serious, perhaps incurable, But even so, deciding to have such a test is not disease later in life? a simple choice. Think about what you would do with the information. One thing you might consider is whether you Patients and doctors face these tough issues every day. Even years from now, when researchers know more about the molecular could do something with what you learn from roots of disease, genetic tests will rarely provide a genetic test. easy answers. In most cases, they won’t even You’ve already read about what you could do if you discovered that you were at high risk provide “yes” or “no” answers. Rather, much like a cholesterol test, they will for developing breast cancer. But what about a predict whether a person’s risk of getting a disease condition that shows up in middle-aged or older is relatively high, low or somewhere in between. people—or one for which there is currently This is because many factors besides genes, includ- no cure? ing lifestyle choices such as diet and exercise, also play a role in determining your health. Good Advice Since the story of genes and health is so complicated and is likely to stay that way for a while, it is very important to consider genetic information in context. Health care professionals known as genetic counselors can be a big help to people who are thinking about getting a genetic test. As a profession, genetic counseling has been around since the mid-1900s. However, only a few specialty clinics offered counseling at that time. Now, genetic counseling is much more widely available. The New Genetics I 21st-Century Genetics 81 GENETICS AND YOU: Crime-Fighting DNA ike your thumbprint, your genes blood or skin cells), DNA forensic tech- are unique, unless you have an nology can identify victims in a natural L identical twin. As such, DNA disaster, such as the December 2004 “fingerprinting” has become a powerful tsunami that ravaged Indonesia and crime-fighting tool. DNA forensics is other Asian countries. DNA fingerprint- a fast-growing specialty that has appli- ing can also match a transplant patient cations beyond putting criminals to an organ donor or establish paternity behind bars. and other family relationships. In addition to identifying suspects Genetic fingerprinting is not limited who leave traces at the scene of a crime to people. It can find small but poten- (for example, strands of hair, drops of tially deadly traces of disease-causing bacteria in food or water, determine whether an expensive horse was sired by a Kentucky Derby winner or figure out whether a puppy’s parents were first cousins. DNA fingerprinting techniques work by looking for differences among gene sequences that are known to vary between people (or between individuals from any species). Scientists read the sequence in a dozen or so places to create a molecular profile. The chances of a molecular fingerprint being the same in two people or two organisms are vanishingly small. 82 National Institute of General Medical Sciences Today’s genetic counselors have gone through Genetics, Business, and the Law a rigorous training process in which they earn Can a scientist claim rights to a gene that he dis- a master’s degree and learn genetics, medicine, covered in worms and that has a nearly identical laboratory procedures, counseling, social work counterpart in humans? and ethics. Genetic counselors do their work Is a person who gave a blood or tissue sample in many different settings, including hospitals, entitled to profits from a company that develops private clinics, government agencies and uni- a drug based on genetic information in her sam- versity laboratories. ple, or to a lifetime supply of the drug? An interesting aspect of the job is that genetic Can a blood or tissue sample that was donated counselors address the needs of entire families, for one purpose be used for an entirely different rather than just individual patients. To evaluate study several years later, without asking the donor genetic risk and its potential consequences, these if that’s OK? professionals gather a family medical history covering generations. These and other issues are hotly debated in ethics and legal circles. Many of the most Field Study The word most often used to refer to applications of genetic research, especially those leading to products for human use, is biotechnology. It involves techniques that use living organisms—or substances derived from those organisms—for various practical purposes, such as making a biological product. One major application of biotech nology is in agriculture. Actually, this is hardly new: Humanity has engaged in agricultural biotechnology for 10,000 years or more. Many traditional farming practices, from plant breeding to animal husbandry, are really forms of biotechnology. But in today’s agricultural industry, biotechnology generally means the use of molecular biology, recombinant DNA technology, cloning and other recent scientific approaches to produce plants and animals with new traits. This usually involves transferring genetic material from one kind of organism into another. Using the same techniques that were developed for putting genes into animals for research purposes, scientists can create crop plants with desirable traits, such as improved flavor or better resistance to insect pests. Transferring specific genes is faster and more efficient than traditional breeding approaches. The United States is home to far more genetically modified crops than anywhere else in the world. In 2009, 85 percent of the country’s corn, 88 percent of its cotton and 91 percent of its soybeans were cultivated from seeds genetically modified to resist plant pests and certain herbicides used to control weeds. Many believe that agricultural biotechnology is an important driver for improving world health. They say that genetic modifications may be the only hope for pest-ravaged crops, such as bananas, that are essential to the economies of poor countries. The creation of edible plants that contain medicine, serve as a form of vaccination The New Genetics I 21st-Century Genetics 83 controversial topics have to do with the idea of patenting life forms. Traditionally, when an inventor comes up with a new idea and wants to sell it—whether it’s a radio-controlled toy boat or a customized laboratory chemical—he or she submits an application to the U.S. Patent and Trademark Office. By issuing patents, the Federal Government gives an inventor ownership of his or her creation. Patents give inventors time to optimize their products and control how their inventions are used, allowing them to make money from their creativity. or deliver extra nutrients—such as the recently developed rice that makes vitamin A—could also contribute in major ways to global health. But opposition from farmers and consumers within and outside the United States has clouded agricultural biotechnology’s future. Some object to the development of plants that are naturally resistant to herbicides, partly out of concern that the trait might jump to weeds, making them impossible to destroy. Environmental advocacy groups worry that genetically modified plants may impact the future biodiversity of our planet by harming beneficial insects and possibly other organisms. However, the U.S. Environmental Protection Agency has stated that there is no evidence to date that indicates that biotech crops have any adverse effects on non-targeted wildlife, plants or beneficial insects. Of course, careful field tests of newly created, genetically modified plants and animals are essential to be sure that they cause no harm to other organisms or to the environment. Biotechnology helps agricultural scientists create crops with desired traits. The majority of cotton and soybeans in the United States are grown with genetically modified seeds that resist viruses and other plant pests. 84 National Institute of General Medical Sciences However, nobody invented a gene, a naturally Patents can be great for business, and they can occurring chemical or a protein, so why should help make the results of research widely available a person or a company be able to own it and through commercial ventures, but they also have control its destiny in the marketplace? the potential to slow research because patent- Patent laws in the United States and Europe holders control how information related to the prohibit anyone from patenting a gene as it exists patent is used. For example, researchers who wish in the human body. But patents have been issued to use patented genetic information may need to for specific medical uses of genetic information. acquire a license first. This can be time-consuming and expensive. Concerned about possible negative effects of patenting genes, the U.S. National Institutes of Health has worked with the U.S. Patent and Trademark Office to establish guidelines for what kind of genetic information can be patented. Since this area of medical research is an ever-moving target, government scientists, policymakers and the courts continue to clarify patent and licensing issues in the hope of keeping data that is valuable for research in the public domain. The New Genetics I 21st-Century Genetics 85 Careers in Genetics Opportunities to be part of genetic and genomic research have never been greater or more exciting. In addition to studying human genes, scientists are gathering information about the genes of many other living things, from microbes that cause disease to model organisms like mice and Drosophila, livestock and crop plants. Although computers do some of the work, this avalanche of information has to be analyzed by thousands and thousands of human brains. In addition to identifying genes, scientists must generated by life scientists, is especially short figure out what the genes do and—even more of qualified workers. As a result, bioinformatics complicated—how they do it. scientists are in high demand. We need laboratory scientists, doctors to do Many careers in genetics and genomics clinical research and treat patients, genetic coun- require advanced degrees such as a Ph.D. or M.D. selors to help people understand the information But people with master’s or bachelor’s degrees are in their genes, and lawyers and ethical specialists also needed to fill thousands of rewarding jobs as who can address legal and policy concerns about genetic counselors, research assistants and lab the use of genetic information. technicians. In especially high demand are people with For more career information, see expertise in mathematics, engineering, computer http://www.ornl.gov/sci/techresources/ science and physics. The field of bioinformatics, Human_genome/education/careers.shtml or which develops hardware and software to store http://science.education.nih.gov/LifeWorks. and analyze the huge amounts of data being 86 National Institute of General Medical Sciences The Tools of Genetics: Informatics and Databases For most of its history, biology managed to This is not surprising when you remember that amass its data mostly with the help of plain old DNA is itself a form of information storage. arithmetic. Gregor Mendel did genetic analysis Where are genetic and genomic data stored? by simply counting the different kinds of off- One of the first biological databases was created spring produced by his peas. By contrast, today’s to store the huge volume of data from experi- genetic research creates too much data for one ments with the fruit fly Drosophila melanogaster. person, or even a scientific team, to understand. Called FlyBase, it has grown into a huge, New technologies are needed to manage this comprehensive, international electronic reposi- huge amount of data. tory for information on Drosophila genetics and Consider this: Gene-sequencing machines molecular biology, run by scientists for scientists. can read hundreds of thousands of nucleotides a The information spans a century’s worth of day. Gene chips are even faster. The information published scientific literature on Drosophila in GenBank®, a widely used database of all melanogaster and its relatives, including their known DNA sequences, now doubles in just complete genome sequences. 3 years. A single laboratory doing cutting-edge genetic research can generate hundreds of gigabytes of data a day, every day. For comparison, 100 gigabytes could hold an entire floor of journals in an academic library. How can anyone make sense of all this information? The only way is to enlist the aid of computers and software that can store the data and make it possible for researchers to organize, search and analyze it. In fact, many of today’s challenges in IMAGE ON COMPUTER SCREEN COURTESY OF TOM SLEZAK, biology, from gene analysis to drug discovery, are really challenges in information technology. LAWRENCE LIVERMORE NATIONAL LABORATORY http://www.dictybase.org/ http://www.yeastgenome.org/ http://www.wormbase.org/ Got It? http://flybase.org/ Do you think modern research tools derived from genomics and bioinformatics will change the practice of medicine? How? If a genetic test revealed that you had a 1 in 100 chance of developing a disease like type 2 diabetes, which can be prevented with Databases like FlyBase are also useful to scientists working with other organisms, like mice or humans. A researcher who discovers a new many laboratory studies (Saccharomyces Genome Database). A key goal is to make sure that all of these mammalian gene may consult FlyBase to see if databases can “talk” to each other. That way, fruit flies have a similar gene and if the database similar discoveries in different organisms— contains hints about what the gene does. Since the important, common threads of all the functions of many genes are retained during biology—can be identified quickly and evolution, knowing what a gene does in one analyzed further. organism often provides valuable clues about lifestyle changes like eating a healthier diet and exercising more, would you change your behavior? What if the risk were 1 in 10? How is genetic engineering similar to traditional farming? How is it different? For this database communication to what it does in another organism, even if the work, researchers in different fields must two species are only distantly related. use the same terms to describe biological A biotechnology company uses processes. The development and use of genetic information from a patient have created their own databases, including those such a universal “ontology”—a common volunteer and develops an effec- dedicated to the investigation of the roundworm language—is helping scientists analyze the tive, profitable medicine. Should Caenorhabditis elegans (WormBase), the soil- complex network of biology that underlies the patient know that he or she dwelling amoeba Dictyostelium discoideum our health. was part of this process? Why or Several other communities of researchers (DictyBase) and the strain of yeast used for why not? What if the research did not lead to any medical advance? 88 National Institute of General Medical Sciences Glossary Amino acid | A building block of proteins. Comparative Genomics | The study There are 20 amino acids, each of which is of human genetics by comparisons with the coded for by three adjacent nucleotides in a genetics of other organisms. DNA sequence. Anticipation | The disease process in which symptoms show up earlier and are increasingly severe in each generation. Diploid | Having two copies of each chromosome. DNA | Abbreviation for deoxyribonucleic acid, the molecule that contains the genetic code for all Biofilm | A slime layer that develops naturally life forms except for a few viruses. It consists of when bacteria congregate on surfaces. two long, twisted chains made up of nucleotides. Bioinformatics | The field of biology specializing in developing hardware and software to store and analyze the huge amounts of data being generated by life scientists. Biotechnology | The industrial use of living Each nucleotide contains one base, one phosphate molecule and the sugar molecule deoxyribose. The bases in DNA nucleotides are adenine, thymine, guanine and cytosine. DNA chip | See microarray. organisms or biological methods derived through DNA polymerase | An enzyme that copies basic research; examples range from genetic engi- DNA. neering to making cheese or bread. Enzyme | A substance (often a protein) that Chromatin | The organization and dense pack- speeds up, or catalyzes, a chemical reaction with- aging of DNA in the nucleus of cells. out being permanently altered or consumed. Chromosome | A cellular structure containing Epigenetics | The study of heritable changes in genes. Chromosomes are composed of DNA and gene function that occur without a change in the proteins. Humans have 23 pairs of chromosomes DNA sequence. in each body cell, one of each pair from the mother and the other from the father. Circadian | Pertaining to a period of about 24 hours; applied especially to rhythmic biologi- Eukaryote | An organism whose cells have a membrane-bound nucleus. Exon | A DNA sequence in a gene that codes for a gene product. cal repetition like the sleep-wake cycle. Gene | A segment of a DNA molecule that Clone | In genetics, the process of making many copies of a gene or a whole organism. The term also refers to the isolation and manipulation of a gene. contains information for making a protein or, sometimes, an RNA molecule. The New Genetics I Glossary 89 Gene chip | See microarray. Gene expression | The process by which Meiosis | The type of cell division that creates egg and sperm cells. genes are first converted to messenger RNA and Microarray | Sometimes called a gene chip or then to proteins. a DNA chip. Microarrays consist of large num- Genetics | The scientific study of genes and heredity— of how particular qualities or traits are transmitted from parents to offspring. bers of molecules (often, but not always, DNA) distributed in rows in a very small space. Microarrays permit scientists to study gene expression by providing a snapshot of all the Genome | All of an organism’s genetic material. Genomics | A “scaled-up” version of genetic research in which scientists can look at large numbers or all of the genes in an organism at genes that are active in a cell at a particular time. MicroRNA | A short piece of single-stranded RNA that does not encode a protein and controls the expression of genes. the same time. Mitochondrion | The cell’s power plant, Haploid | Having one copy of each chromosome, as in a sperm or egg. supplying the energy to carry out all of the cell’s jobs. Each cell contains up to 1,000 mitochon- Haplotype | A set of closely linked genes or dria. The structures contain their own small DNA polymorphisms inherited as a unit. genomes, called mitochondrial DNA. Histone | A type of protein found in chromo- Mutation | A change in a DNA sequence. somes; histones attached to DNA resemble “beads on a string.” Nucleotide | A building block of DNA or RNA. It includes one base, one phosphate mole- Homeobox | A DNA sequence found in genes cule and one sugar molecule (deoxyribose in involved in the regulation of the development DNA, ribose in RNA). of animals, fungi and plants. Imprinting | The phenomenon in which a gene may be expressed differently in an offspring depending on whether it was inherited from the father or the mother. Intron | A DNA sequence, or the RNA sequence transcribed from it, that interrupts the sequences coding for a gene product (exon). Nucleus | The structure in the eukaryotic cell containing most of its genetic material. Pharmacogenetics | The study of how people’s genetic make-up affects their responses to medicines. Protein | A molecule consisting of subunits called amino acids. Proteins are the cell’s main building materials and do most of a cell’s work. 90 National Institute of General Medical Sciences Recombinant DNA | Hybrid DNA produced Sequencing | Sometimes called DNA sequenc- in the laboratory by joining pieces of DNA from ing or gene sequencing. Discovering the exact different sources. order of the building blocks (see nucleotides) of Replication | The process by which DNA a particular piece of DNA. copies itself in order to make a new genome to Stem Cell | A cell that can develop into many pass on to a daughter cell. different cell types in the body. Ribosome | The cell structure in which pro- Systems biology | A field that seeks to study teins are manufactured. Most cells contain the relationships and interactions between vari- thousands of ribosomes. ous parts of a biological system (metabolic RNA | Abbreviation for ribonucleic acid, the molecule that carries out DNA’s instructions for making proteins. It consists of one long chain pathways, organelles, cells and organisms) and to integrate this information to understand how biological systems function. made up of nucleotides. Each nucleotide contains Telomere | A repeated DNA sequence that caps one base, one phosphate molecule and the sugar the ends of chromosomes. molecule ribose. The bases in RNA nucleotides are adenine, uracil, guanine and cytosine. RNA interference (RNAi) | A gene-silencing process in which double-stranded RNAs trigger the destruction of specific RNAs. Transcription | The first major step in gene expression, in which the information coded in DNA is copied into a molecule of RNA. Translation | The second major step in gene expression, in which the instructions encoded in RNA polymerase | An enzyme that transcribes RNA are carried out by making a protein or start- a DNA sequence, creating mRNA. ing or stopping protein synthesis. RNA splicing | The process by which introns Variant | A different version of a gene, one that are removed and exons are joined together has a slightly different sequence of nucleotides. from an RNA transcript to produce an mRNA molecule. Discrimination Prohibited Under provisions of applicable public laws enacted by Congress since 1964, no person in the United States shall, on the grounds of race, color, national origin, handicap, or age, be excluded from participation in, be denied the benefits of, or be subjected to discrimination under any program or activity (or, on the basis of sex, with respect to any education program or activity) receiving Federal financial assistance. In addition, Executive Order 11141 prohibits discrimination on the basis of age by contractors and subcontractors in the performance of Federal contracts, and Executive Order WHAT IS NIGM S? The National Institute of General Medical Sciences (NIGMS) supports basic research on genes, proteins and cells. 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